CN115765119B

CN115765119B - Charging management method of energy storage power supply, energy storage power supply and storage medium

Info

Publication number: CN115765119B
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: 2023-07-28
Anticipated expiration: 2043-01-10
Also published as: CN115765119A

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 attribute and connection information of equipment to be charged based on the connection state of the equipment to be charged; according to the attribute, determining the related information of the equipment to be charged; determining the priority of the equipment to be charged according to the preset equipment priority and the related 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 be used for preferentially selecting which equipment is charged according to the priority of the equipment, and the problem that the charging duration of each equipment to be charged is increased due to the fact that the equipment to be charged is charged simultaneously after the equipment to be charged is connected can be avoided. Meanwhile, by the method provided by the application, when a 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 application relates to the technical field of energy storage power supplies, in particular to a charging management method of an energy storage power supply, the energy storage power supply and a storage medium.

Background

The portable energy storage power supply, also called portable outdoor power supply, is a standby power supply or emergency power supply with the weight of usually not more than 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 charge 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 supplying power to low-power household appliances such as an electric cooker.

However, since the maximum output current of the portable energy storage power supply is usually fixed, but there may be more than one to-be-charged device, if there are multiple to-be-charged devices connected to the portable energy storage power supply at the same time, the portable energy storage power supply will split the output current of the portable energy storage power supply when charging the to-be-charged devices, so as to meet the requirement of simultaneously charging the multiple to-be-charged devices. In this case, the time required for the multiple connected devices to be charged to reach the fully charged state or for the electric quantity to meet the needs 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 than the original time period to meet the charging needs. At this time, if the user wants to use a certain device, he 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 method for charging management of 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;

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

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

By the method, the attribute and the connection information of the connected equipment to be charged can be obtained 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 attribute, and then determining the priority of the connected devices to be charged according to the preset device priority and the relevant information, so as to determine the first-stage charging device according to the connection information and the priority and charge the first-stage charging device after the charging state is adjusted. The method can enable 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 duration 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 a 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 related information includes an applicable current of the connected device to be charged; according to the connection information and the priority, determining a first-stage charging device and adjusting the charging state of the first-stage charging device to charge the first-stage charging device, including:

determining the applicable current of the first-stage charging equipment according to the related 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 corresponding connection port of the first-stage charging equipment to charge the first-stage charging equipment.

By means of 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 devices, so that the first-stage charging devices can be charged at the highest 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 less time, and the experience of the user is improved.

Optionally, the method further comprises:

acquiring an 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 value, determining second-stage charging equipment according to the connection information and the priority;

and shorting the connection 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 mode that this embodiment provided, when the electric quantity value of first level charging equipment reached first default electric quantity threshold value, it can satisfy user's user demand to indicate the electric quantity of first level charging equipment, and at this moment, can not charge first level charging equipment to the state of being full of completely. 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 charged. By the method, on the premise of meeting the use requirements of users, the charging efficiency of all connected equipment to be charged can be improved. And the devices can meet the use requirements of users in a shorter time.

Optionally, the method further comprises:

acquiring the external environment state at the current moment;

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

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

setting the connected key equipment as 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 means of the method provided by the embodiment, when the key devices are in different external environment states, key devices in different external environment states can be determined, so that connection states of the key devices are determined, connected key devices are determined, the connected key devices are set as first-stage charging devices, and charging states are adjusted to be the first-stage charging devices at the same time. The method can more flexibly adjust the charging states of the connected equipment to be charged when the equipment is in different external environment states, so that the use requirements of users are met as much as possible under different time and different conditions, and the waiting time of the users under different time and different conditions is reduced.

Optionally, the method further comprises:

according to the connection state of the key equipment, determining the key equipment which is not connected at the current moment;

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

and determining whether to start a voice prompt to play the connection prompt of the unconnected key equipment according to the weight of the unconnected key equipment.

By means of the method provided by the embodiment, unconnected key devices can be determined according to the connection state of the key devices, and weights of the unconnected key devices are determined according to the external environment state at the current moment, so that whether to start the voice reminding playing corresponding connection prompts is determined. By the method, the user can be reminded in time, the situation that the unconnected key equipment with higher weight is powered down when the user is used 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 steps of:

according to the charging mode supported by the connected equipment to be charged, determining the connected equipment to be charged supporting wireless charging;

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

Through the mode provided by the embodiment, when some devices supporting wireless charging are connected to the corresponding connection ports for charging, voice reminding can be carried out, so that the devices can be charged in the wireless charging slot, the connection ports are idle, the charging requirements of other devices not supporting wireless charging are met, and the use efficiency of the energy storage power supply is improved.

Optionally, the method further comprises:

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 the 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 current time meets the electricity consumption requirement through solar charging according to the external environment state;

and if the current time does not meet the electricity demand through solar charging, starting a voice prompt to play a low electricity warning.

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

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 related 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 related information;

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

Optionally, the state adjustment module is specifically configured to:

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

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

acquiring the electric quantity of the energy storage power supply;

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 capable of being loaded by the processor and performing the method of the first aspect.

In a fourth aspect, the present application provides a computer readable storage medium storing a computer program capable of being loaded by a processor and performing 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, a brief description will be given below of the drawings that are needed in the embodiments or the prior art descriptions, it being obvious that the drawings in the following description are some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort to a person skilled in the art.

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 method for managing charging of an energy storage power supply according to an embodiment of the present application;

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 more clear, the technical solutions of 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 will be apparent that the embodiments described are some, but not all, of the embodiments of the present application. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, are intended to be within the scope of the present application.

In addition, the term "and/or" herein is merely an association relationship describing an association object, and means that three relationships may exist, for example, a and/or B may mean: a exists alone, A and B exist together, and B exists alone. In this context, unless otherwise specified, the term "/" generally indicates that the associated object is an "or" relationship.

Embodiments of the present application are described in further detail below with reference to the drawings attached hereto.

The maximum output current of a portable energy storage power source (i.e., the energy storage power source described above) is typically fixed, 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 into the portable energy storage power supply at the same time, the portable energy storage power supply can split the output current of the portable energy storage power supply when the devices to be charged are charged, so that the requirement of simultaneously charging the devices to be charged is met. In this case, the time required for the connected devices to be charged to reach the fully charged state or for the electric quantity to meet the user's requirement is longer than the time required for only one device to be charged, which means that each device to be charged needs longer than the original time period to meet the charging requirement. At this time, if the user wants to use a certain device, he needs to wait for a longer time, which may affect the normal use requirement of the user. In addition, some other commonly used devices of the user may not be available to the user in time.

Based on the above, the application provides a charging management method of an energy storage power supply, the 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, according to the acquired attribute, determining the related information of the connected equipment to be charged. And determining the priority of the connected equipment to be charged through 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, a user can use the first-stage charging equipment at the first time, and the problem that all connected equipment to be charged cannot meet the use requirement of the user in time due to energy storage power supply split is avoided.

Fig. 1 is a schematic view of an application scenario provided in the present application. The energy storage power supply that this application relates to distributes a plurality of connection ports, can satisfy the charging demand of a plurality of equipment of waiting to charge that use different grade type connection ports. When a user needs to charge a plurality of devices to be charged and there is a difference in demand among the devices to be charged, the method provided by the application can be used for solving the problem. When a plurality of devices to be charged are accessed, the attribute and the connection information of the devices to be charged are acquired, then the priority of the devices to be charged is determined after a series of operations, and the charging state of the devices to be charged is adjusted according to the priority and the connection information, so that the purpose of charging is achieved.

Reference may be made to the following examples for specific implementation.

Fig. 2 is a flowchart of a method for managing charging of an energy storage power supply according to an embodiment of the present application, where the method of the present 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 that are charged and have sufficient power to be used can be considered to be devices to be charged. The connection state of the device to be charged may be understood as a state of whether the device to be charged is connected to the energy storage power supply.

The attribute of the equipment to be charged comprises the type of the equipment to be charged, the model of the equipment to be charged, the charging mode supported by the equipment to be charged and the like. The type of device to be charged may include a lighting device, a communication device, a heating device, etc. The model of the device to be charged may include a model of the lighting device, such as: household lighting, engineering lighting, commercial lighting, which may also include brands and corresponding brand models of household lighting, engineering lighting, commercial lighting; the model of the communication device may include, for example: cell phones, computers, telephone watches, etc., which can also include brands and corresponding brands and models of cell phones, computers, telephone watches; the model of the heating appliance may include the brand of the heating appliance and a corresponding brand model. The charging mode supported by the device to be charged may include: slow charging, fast charging and wireless charging, wherein slow charging means charging by using alternating current, the time required for reaching a full charge state is long, fast charging can be understood as enabling a battery to reach the full charge state in one to two hours, or compared with the time spent for fast charging, wireless charging can be understood as realizing the battery charging mode without passing through a connecting wire.

In some implementations, some devices to be charged may support both fast charging, slow charging, wireless charging. When these devices supporting both fast charge, slow charge, wireless charge are charged via a connection line, it is generally preferred to use fast charge. The user can also perform relevant settings in the device, so that the device can select a corresponding charging mode for charging according to the setting condition of the user.

The connection information of the device to be charged may include a connection port type, a connection port number. The connection port types may include: two-port sockets, three-port sockets, USB interfaces, etc. The energy storage power supply provided by the application can be provided with a plurality of different connection port types, so that the corresponding connection port number can be set for each connection port type position for distinguishing.

Specifically, according to the connection state of the devices to be charged, after determining which devices to be charged are connected to the energy storage power supply, the energy storage power supply can acquire the attribute and the 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 attribute.

The relevant information of the equipment to be charged mainly comprises the model of the equipment to be charged, such as the model corresponding to the brand, and in addition, the relevant information of the equipment to be charged can also comprise the charging modes supported by the equipment to be charged, the applicable current corresponding to the charging modes and the like.

Specifically, according to the attribute of the to-be-charged device related to the step S201, the relevant information of the to-be-charged devices connected to the energy storage power source is determined.

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

The preset equipment priority can be set when the energy storage power supply is produced, and can also be set according to the use frequency of 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 multiple layers of priorities can be set according to time, weather or other basis. When some emergency or sudden change occurs, the energy storage power supply can detect the emergency or sudden change, and the charging adjustment of some equipment to be charged is performed according to the set equipment priority, so that the equipment 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 priority is actually set, a large number of equipment use data samples can be collected, then the equipment to be charged is classified according to the class of the equipment, after the classification is finished, the equipment to be charged is ordered according to the classification condition and the total charging times of all the equipment in the class and the order of the priority of the classes is determined according to the order from more to less, so that the priority of the classes is firstly determined according to the order. And sequencing the devices to be charged in each category from more to less according to the number of charging times, thereby determining 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 the equipment to be charged can be further determined to be charged with priority.

In other implementations, the multi-layer priority may be set according to weather conditions or usage scenarios, so that the priority of each device to be charged may be more accurately determined in different usage scenarios or different weather conditions, and then the charging state is adjusted and charged.

When the priority of the multiple layers is set according to weather conditions or usage scenarios, the priority of the first layer can be set according to the charging times of the equipment in daily life, and then the priority of other layers can be set according to actual weather conditions or usage scenarios. For example, when playing outside, this stored energy power source may need to charge devices such as cameras, cell phones, phone watches, navigators, projectors, etc. At this time, the priority may be set according to the frequency of use of these devices during the trip. For example, the frequency of use of a cell phone is high, the camera is next, the phone watch is next, and finally the projector is; or the frequency of the use of the mobile phone is very high, the phone watch is second, the camera is next, and finally the projector is arranged. How often the usage is, can be learned statistically by collecting a large amount of upstream device usage data.

In a practical implementation, priorities may also be set between the multi-layer priorities. For example, the first layer of priority is a daily common condition, 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 as the case may be, that the second layer priority > the third layer priority > the first layer priority. With this form of arrangement, when a multi-level priority is triggered, the priority relationship is more explicit, so that subsequent adjustments are made according to this priority relationship.

Specifically, the priority of the devices to be charged which have been confirmed to be connected is determined according to the preset device priority and the related information of the devices to be charged which have been confirmed to be connected in the steps.

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

The first-stage charging device may be understood as the device with the highest priority, and the energy storage device may be charged with priority when multiple devices to be charged are accessed. One or a plurality of the above-mentioned materials may be used.

The charge 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, but is not charged although connected. 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 some connection ports corresponding to devices to be charged are in an on state, then the connection ports corresponding to other devices to be charged may be set to a short-circuit state.

Specifically, according to the connection information and the priority obtained in the above steps, the first-stage charging equipment capable of charging with priority is determined, and after the charging states of the first-stage charging equipment are adjusted to be on states, the charging of the first-stage charging equipment is realized.

By the method, the attribute and the connection information of the connected equipment to be charged can be obtained 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 attribute, and then determining the priority of the connected devices to be charged according to the preset device priority and the relevant information, so as to determine the first-stage charging device according to the connection information and the priority and charge the first-stage charging device after the charging state is adjusted. The method enables the energy storage power supply to preferentially select which equipment to charge 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 a 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 includes 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 a current distribution scheme, adjusting the output current of the corresponding connection port of the first-stage charging equipment so as to achieve the purpose of charging the first-stage charging equipment. Specifically, it may include: determining the applicable current of the first-stage charging equipment according to the related information; determining a current distribution scheme of the energy storage power supply according to the applicable current; according to the current distribution scheme, the output current of the corresponding connection port of the first-stage charging equipment is adjusted to charge the first-stage charging equipment.

The applicable current is understood to be the current value at which each device can reach a full state at the fastest charging speed when it is charged.

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

In some implementations, there may be multiple first charging devices, where the total current of the stored energy power source may not have a way to satisfy all of the first stage charging devices to charge with the applicable current. Therefore, when the situation is faced, the device with the front priority can be determined according to the priority of the first-stage charging device, the devices are charged according to the corresponding applicable current preferentially, and the ranked devices are distributed according to the residual output current of the preferential energy storage power supply. In a specific implementation process, a current threshold may be set, where the current threshold may be set according to an 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 allocated to the device to be charged with the later priority is found to be less by the allocation, the allocated output current is compared with the above-set current threshold. 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 below the current threshold, this distributed output current is not suitable because it takes too long to charge the device to be charged. At this time, this less suitable device to be charged may be eliminated from the first-stage charging devices.

By means of 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 highest 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 a user can be met by shorter charging time, and the experience of the user is improved.

In some embodiments, it is determined whether to short-circuit a connection port of the first stage charging device by a charge value of the first stage charging device, and then the state of charge of the second stage charging device is adjusted to charge the second stage charging device. Specifically, it may include: 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 the first preset electric quantity threshold value, determining second-stage charging equipment according to the connection information and the priority; and shorting out 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 can be understood as an electric quantity value which can meet the use requirement of the first-stage charging equipment, and the preset electric quantity threshold can be set according to the length of the electric quantity value of the first-stage charging equipment meeting 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. The first preset power threshold may be set fixedly, that is, all devices to be charged included in the first-stage charging device use the fixed first preset power threshold, or may be set separately for all devices to be charged included in the first-stage charging device, and may be collectively referred to as a first preset power threshold.

The second-stage charging device may be understood as one or more connected devices to be charged, which are determined to have a priority level next to that of the first-stage charging device, according to the above-described preset device priority level. The manufacturer may set the number of charging devices per stage according to the specific capabilities of the stored energy power source.

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 value of the to-be-charged equipment contained in the first-stage charging equipment is higher than the first preset electric quantity threshold value, the fact that all to-be-charged equipment in the first-stage charging equipment can meet the use requirement of a user is indicated, at the moment, the second-stage charging equipment is determined according to the connection information and the priority, and meanwhile, the connection port corresponding to the first-stage charging equipment can be short-circuited, namely, the first-stage charging equipment 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 equipment. And adjusts the charging state of the second-stage charging device to the on state to charge it.

Through the mode that this embodiment provided, when the electric quantity value of first level charging equipment reaches first default electric quantity threshold value, it can satisfy user's user demand to indicate the electric quantity of first level charging equipment. At this time, the first-stage charging device may not be charged to a completely full state, but after reaching the first preset power threshold, the connection port corresponding to the first-stage charging device may be shorted, 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 meet the use requirements of users in a shorter time.

In some embodiments, the key device to be charged at the current moment can be determined according to the external environment state, then the connected key device is set as the first-stage charging device at the current moment according to the connection state of the key device, and the charging states of the devices are adjusted to charge the devices. Specifically, it may include: acquiring the external environment state at the current moment; according to the external environment state, determining key equipment to be charged at the current moment; acquiring a connection state of key equipment and determining the connected key equipment; 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 weather conditions of the ambient environment. In a specific implementation manner, 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 time at the current moment can be known through the module, and the time at the current moment can reflect the external environment state at the current moment, such as a few days bright and a few days dark.

The key device can be understood as a device which needs to be charged preferentially according to the external environment state at the current moment. May be identical to the second-layer priority set according to weather conditions among the plurality of layers of priorities referred to in the above-described preset device priorities. For example, it may be required to illuminate when it is detected that the ambient light has been darkened at the current time or when the current time is acquired at 18:30 a.m. The lighting device can be used as a key device. In addition, all devices that need to be charged with priority in the current environmental state, whether or not connected to the stored energy power source, can be used as key devices.

Specifically, the external environment state at the current moment is obtained, and key equipment needing to be charged with priority 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, and adjusting the charging states of the key devices to be on states so as to charge 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 a voice prompt according to the weight, and playing a connection prompt. Specifically, it may include: according to the connection state of the key equipment, determining the key equipment which is not connected at the current moment; according to the external environment state, determining the weight of the unconnected key equipment; and determining whether to start the voice prompt to play the connection prompt of the unconnected key equipment according to the weight of the unconnected key equipment.

The weights of the unconnected key devices are understood to be the weights of all key devices at the current moment in time, i.e. the importance of these unconnected key devices at the current moment. For example, when the current time is blackish and the lighting device is needed urgently, the lighting device can 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 stored energy power supply. This requires that the intelligent voice assistant be set in advance when the energy storage power supply is produced, and the setting content may include a wake-up instruction, a reminder instruction, and the like. A wake-up instruction may be understood as an instruction for a user to wake up the energy storage power supply to perform certain operations. The reminding instruction can be understood as reminding 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 weights of the unconnected key devices in all key devices according to the acquired external environment state. And then determining whether to start the voice prompt to play the connection prompt of the unconnected key devices according to the weight of the unconnected key devices in all key devices.

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

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

By means of the method provided by the embodiment, unconnected key devices can be determined according to the connection state of the key devices, and weights of the unconnected key devices are determined according to the external environment state at the current moment, so that whether to start the voice reminding playing corresponding connection prompts is determined. By the method, the user can be reminded in time, the situation that the user finds that the key equipment which is not connected but has higher weight is powered off when in use 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 obtained, and then the device to be charged supporting wireless charging is determined. After the devices to be charged supporting wireless charging are connected to the connection port, voice reminding is started so that the devices to be charged supporting wireless charging can be adjusted to the wireless charging slot. Specifically, it may include: according to a charging mode supported by the equipment to be charged, determining the equipment to be charged supporting wireless charging; when the equipment to be charged supporting wireless charging is connected to the corresponding connection port, the voice reminding play connection port is started to adjust the reminding.

The wireless charging groove sets up on the energy storage power supply that this application provided, can carry out wireless charging for the equipment that supports wireless charging. And the connection port of the energy storage power supply is saved. The wireless charging slot can adjust the output power according to the placed devices, so that each device placed in the wireless charging slot can be charged at the fastest possible charging speed.

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

In the 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 first. If the wireless charging slot is detected to be in an idle state, voice prompt can be carried out. If the wireless charging slots are detected to be used, voice reminding can be omitted when the devices to be charged supporting wireless charging are connected to the corresponding connection ports.

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

In some embodiments, the electric quantity of the energy storage power supply can be obtained, and when the electric quantity of the energy storage power supply is low, whether the electricity consumption requirement is met through solar charging can be determined according to the external environment state. If not, a voice prompt can be started to play a low-electricity warning, so that a user can charge the energy storage power supply in time. Specifically, it 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 current moment meets the electricity consumption requirement through solar charging according to the external environment state; and if the current time does not meet the electricity demand through solar charging, starting a voice prompt to play a low electricity warning.

The second preset power threshold may be understood as a minimum power value of the energy storage power supply that can meet the charging requirement, or may be understood as a power value of the energy storage power supply that is insufficient to support the charging of the device to be charged. In addition, when the electric quantity of most equipment is low, a certain damage may be caused to the battery of the equipment if the equipment is still in an operation state, so that the second preset electric quantity threshold value can be understood as an electric quantity minimum value which does not cause any damage to the battery of the energy storage power supply in the operation process. In this embodiment, the second preset power threshold may represent a power minimum value that does not cause any damage to the battery of the energy storage power supply during 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 that a solar panel is arranged on the energy storage power supply, and the energy storage power supply can be charged by absorbing light energy and converting the light energy into electric energy. Because solar charging costs less money than other modes and is also the most environmentally friendly form, the charging modes can be prioritized when the energy storage power supply is produced, for example, solar charging mode > mains charging mode > generator charging mode > vehicle charging. By setting the priority of the energy storage power supply, the energy storage power supply can complete 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 at the moment is determined. If the electric quantity of the energy storage power supply is higher than the second preset electric quantity threshold value, the energy storage power supply can continue to charge some equipment to be charged, and the damage to the battery arranged in the energy storage power supply is avoided. If the electric quantity of the energy storage power supply is lower than the second preset electric quantity threshold value, the fact that the energy storage power supply is charged for the equipment to be charged again at the moment is indicated, and the damage to the battery arranged in the energy storage power supply is likely to happen. If the electric quantity of the energy storage power supply is found to be lower than the second preset electric quantity threshold value through comparison, determining whether the energy storage power supply can meet the electricity consumption requirement of a user if the energy storage power supply is charged in a solar mode according to the external environment state at the current moment. If the energy storage power supply can meet the electricity demand of a user through solar energy charging, the energy storage power supply is directly charged. If the energy storage power supply can not meet the electricity demand of the user through the solar energy charging, the user can be informed of timely charging the energy storage power supply by reminding to play a low electricity warning through voice.

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

In other implementations, a fixed period of time may be provided to utilize solar energy to timely replenish the stored energy power source with power.

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

The information obtaining module 301 is 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, related 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 related information;

and the state adjustment module 304 is 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 adjustment module 304 is specifically configured to:

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

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

Optionally, the energy storage power supply 300 further includes a key device adjustment module 306 for:

acquiring the external environment state at the current moment;

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 reminding module 308, configured to:

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

acquiring the electric quantity of the energy storage power supply;

The apparatus of this embodiment may be used to perform the method of any of the foregoing embodiments, and its implementation principle and technical effects are similar, and will not be described herein again.

Fig. 4 is a schematic structural diagram of another energy storage power supply according to an embodiment of the present application, as shown in fig. 4, an energy storage power supply 400 of the present 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 that performs the methods of the above-described embodiments.

Wherein the processor 402 is coupled to the memory 401, e.g. via a bus.

Optionally, the stored energy 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 is not limited to the embodiment of the present application.

The processor 402 may be a CPU (Central Processing Unit ), general purpose processor, DSP (Digital Signal Processor, data signal processor), ASIC (Application Specific Integrated Circuit ), FPGA (Field Programmable Gate Array, field programmable gate array) or other programmable logic device, transistor logic device, hardware components, or any combination thereof. Which may implement or perform the various exemplary logic blocks, modules, and circuits described in connection with this disclosure. Processor 402 may also be a combination that implements computing functionality, e.g., comprising one or more microprocessor combinations, a combination of a DSP and a microprocessor, etc.

A bus may include a path that communicates information between the components. The bus may be a PCI (Peripheral Component Interconnect, peripheral component interconnect standard) bus or an EISA (Extended Industry Standard Architecture ) bus, or the like. The buses may be divided into address buses, data buses, control buses, etc. For ease of illustration, the figures are shown with only one bold line, but not with only one bus or one type of bus.

Memory 401 may be, but is not limited to, 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, compact disc Read Only Memory) or other optical disk storage, optical disk storage (including compact discs, laser discs, optical discs, digital versatile discs, blu-ray discs, etc.), magnetic disk storage media or other magnetic storage devices, 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.

The memory 401 is used for storing application program codes for executing the present application and is controlled to be executed by the processor 402. The processor 402 is configured to execute the application code stored in the memory 401 to implement what is shown in the foregoing method embodiment.

Wherein the stored energy 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 stationary terminals such as digital TVs, desktop computers, and the like. But may also be a server or the like. The stored energy power supply shown in fig. 4 is only an example and should not impose any limitation on the functionality and scope of use of the embodiments of the present application.

The energy storage power supply of the present embodiment may be used to implement the method of any of the foregoing embodiments, and its implementation principle and technical effects are similar, and will not be described herein.

The present application also provides a computer-readable storage medium storing a computer program capable of being loaded by a processor and executing the method in the above embodiments.

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

Claims

1. A method of charging management of an energy storage power supply, the energy storage power supply comprising a plurality of different types of connection ports for outdoor power, the method comprising:

acquiring the external environment state at the current moment;

acquiring the attribute and the connection information of the connected equipment to be charged;

according to the attribute, determining the related information of the connected equipment to be charged; the related information comprises the applicable current of the connected equipment to be charged; the applicable current is used for representing a current value for enabling the equipment to be charged to reach a full-charge state at the fastest charging speed;

determining a first-stage charging device from the connected devices to be charged according to the connection information and the device priority corresponding to the external environment state at the current moment;

according to the external environment state at the current moment, determining the equipment priority corresponding to the external environment state at the current moment from preset multi-layer equipment priority; the preset priority of the multi-layer equipment is determined according to the environmental state; the environment states comprise weather conditions and use scenes, wherein the weather conditions comprise time, light intensity and day and night conditions;

Determining key equipment to be charged at the current moment according to the equipment priority corresponding to the external environment state at the current moment;

acquiring a connection state of the key equipment, determining connected key equipment, and taking the connected key equipment as first-stage charging equipment;

determining a current distribution scheme of the energy storage power supply according to the applicable current of the first-stage charging equipment;

according to the current distribution scheme, adjusting the output current of a connecting port corresponding to the first-stage charging equipment to charge the first-stage charging equipment;

the related information also comprises a charging mode supported by the connected equipment to be charged, and the energy storage power supply comprises a wireless charging slot; the method further comprises the steps of:

2. The method as recited in claim 1, further comprising:

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

3. The method as recited in claim 1, further comprising:

4. The method as recited in claim 1, further comprising:

acquiring the electric quantity of the energy storage power supply;

5. An energy storage power supply, comprising:

the environment state acquisition module is used for acquiring the external environment state at the current moment;

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

the information determining module is used for determining the related information of the connected equipment to be charged according to the attribute; the related information comprises the applicable current of the connected equipment to be charged; the applicable current is used for representing a current value for enabling the equipment to be charged to reach a full-charge state at the fastest charging speed;

the device determining module is used for determining first-stage charging devices according to the connection information and the device priority corresponding to the external environment state at the current moment;

the device priority determining module is used for determining the device priority corresponding to the external environment state at the current moment from preset multi-layer device priorities according to the external environment state at the current moment; the preset priority of the multi-layer equipment is determined according to the environmental state; the environmental conditions include weather conditions, usage scenarios, time, light intensity, and diurnal conditions;

The key equipment determining module is used for determining key equipment which needs to be charged at the current moment according to equipment priority corresponding to the external environment state at the current moment, and taking the connected key equipment as first-stage charging equipment;

the scheme determining module is used for determining a current distribution scheme of the energy storage power supply according to the applicable current of the first-stage charging equipment;

the charging module is used for adjusting the output current of the connecting port corresponding to the first-stage charging equipment to charge the first-stage charging equipment according to the current distribution scheme;

the second voice reminding module is used for determining the connected equipment to be charged supporting 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 is connected to the corresponding connection port, starting the voice reminding play connection port adjustment prompt.

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

the memory is used for storing program instructions;

the processor is configured to invoke and execute program instructions in the memory to perform a method for managing charging of an energy storage power supply according to any of claims 1-4.

7. A computer-readable storage medium, wherein the computer-readable storage medium has a computer program stored therein; the computer program, when executed by a processor, implements a method of charging management of an energy storage power supply as claimed in any one of claims 1-4.