CN115709666A - Battery replacement control method and device for charging cabinet - Google Patents

Abstract

The present disclosure provides a charging cabinet battery replacement control method and device, the method is applied to a charging cabinet, and the method includes: in response to the fact that the charging cabinet is detected to be in a disconnected state, a first password input by a user is acquired, and the first password is used for requesting to replace a battery; determining a first battery swap request number for generating the first password according to the first password; and in response to that target battery swapping request times are not detected or that the first battery swapping request times are different from at least one target battery swapping request time, executing a battery swapping operation, where the target battery swapping request times are battery swapping request times corresponding to the battery swapping operation executed by the charging cabinet. Therefore, the charging cabinet can provide the battery replacement service for the user under the condition of network disconnection.

Description

Battery replacement control method and device for charging cabinet

The present disclosure is a divisional application of an invention application 2020115676027 filed on 25.12.2020/12.2020, "method and apparatus for controlling battery replacement in a charging cabinet".

Technical Field

The disclosure relates to the technical field of charging cabinets, in particular to a battery replacement control method and device of a charging cabinet.

Background

Along with the high-speed development of the electric vehicle industry, the electric vehicle is more and more popular in use, and the electric vehicle becomes an excellent tool for people to travel in short distance. However, the battery endurance problem of the electric vehicle cannot meet the travel requirement of people.

At present, a charging cabinet of a battery of an electric vehicle is arranged on a street, a parking shed and the like, so that an electric vehicle user can conveniently replace the battery of the electric vehicle. After a user arrives at the charging cabinet, the terminal equipment is used for scanning the two-dimensional code displayed on the screen of the charging cabinet to obtain the identification of the charging cabinet, a battery replacement request comprising the identification of the charging cabinet is sent to the server, then the server sends a battery replacement instruction to the charging cabinet, and the charging cabinet provides a battery replacement service after receiving the battery replacement instruction. The charging cabinet is in communication with the server through General Packet Radio Service (GPRS) or Global System for Mobile Communications (GSM), but the charging cabinet cannot communicate with the server under the condition that the charging cabinet is disconnected, so that a power switching instruction sent by the server cannot be received, and further, a power switching Service cannot be provided for a user.

Disclosure of Invention

The present disclosure provides a battery swapping control method and device for a charging cabinet, so as to overcome a problem that a battery swapping service cannot be provided for a user when the charging cabinet is disconnected from a network.

In a first aspect, the present disclosure provides a charging cabinet swapping control method, which is applied to a charging cabinet, and the method includes:

responding to the situation that the charging cabinet is detected to be in a disconnected state, and acquiring a first password input by a user, wherein the first password is used for requesting to replace a battery;

determining a first battery swap request number for generating the first password according to the first password;

and in response to that target battery swapping request times are not detected or that the first battery swapping request times are different from at least one target battery swapping request time, executing a battery swapping operation, where the target battery swapping request times are battery swapping request times corresponding to the battery swapping operation executed by the charging cabinet.

Optionally, before determining, according to the first password, the number of times of the first battery replacement request for generating the first password, the method further includes:

respectively generating corresponding reference passwords according to at least one reference battery replacement request frequency of the charging cabinet;

the determining, according to the first password, a number of times of a first battery swap request for generating the first password includes:

inquiring a reference password according to the first password;

and determining the reference battery swapping request times for generating the target reference password as the first battery swapping request times in response to the fact that the target reference password is the same as the first password.

Optionally, the generating the corresponding reference passwords according to the at least one reference battery replacement request number of times of the charging cabinet includes:

and respectively generating corresponding reference passwords according to the at least one reference battery replacement request frequency of the charging cabinet and the current time node.

Optionally, the time node is a date.

Optionally, after the battery swap operation is performed, the method further includes:

and marking the first power swapping request times as target power swapping request times.

Optionally, the method further includes:

after battery replacement operation is executed, generating battery replacement information of the user, wherein the battery replacement information of the user comprises the first password and a battery identifier, and the battery identifier is an identifier of a battery replaced by the battery replacement operation executed by the charging cabinet;

and in response to the detection of the networking of the charging cabinet, sending the battery replacement information of at least one user generated during the disconnection of the charging cabinet to a server.

Optionally, the method further includes:

responding to the detection of networking of the charging cabinet, and receiving one or more battery replacement request times sent by a server, wherein the one or more battery replacement request times are battery replacement request times generated by the server during the network disconnection period of the charging cabinet;

and marking the received one or more battery swapping request times as target battery swapping request times.

Optionally, the method further includes:

responding to the networking of the charging cabinets, receiving a battery replacing instruction sent by the server, wherein the battery replacing instruction is used for indicating the charging cabinets to execute battery replacing operation;

according to the battery swapping instruction, executing a battery swapping operation, obtaining the battery swapping request times which are recently marked as the target battery swapping request times, accumulating the battery swapping request times which are recently marked as the target battery swapping request times by 1, obtaining the battery swapping request times corresponding to the battery swapping instruction, and marking the battery swapping request times corresponding to the battery swapping instruction as the target battery swapping request times.

Optionally, before the obtaining the first password input by the user, the method further includes:

in response to detecting that the charging cabinet is disconnected, displaying an input interface for requesting a password for replacing the battery;

the acquiring of the first password input by the user comprises:

and acquiring the first password input by the user on the input interface.

Optionally, the method further includes:

and deleting the target battery replacement request times of the charging cabinet at preset time intervals.

In a second aspect, the present disclosure provides a charging control method for a charging cabinet, which is applied to a server, and the method includes:

receiving a battery swapping request sent by terminal equipment of a user, wherein the battery swapping request comprises an identifier of a charging cabinet;

if the charging cabinet is determined to be in the network disconnection state according to the identifier of the charging cabinet, acquiring the number of times of a recently generated battery replacement request of the charging cabinet, and generating the number of times of the battery replacement request corresponding to the battery replacement request according to the number of times of the recently generated battery replacement request;

generating a first password according to the battery swapping request times corresponding to the battery swapping request;

and sending the first password to the terminal equipment.

Optionally, the generating a first password according to the number of times of the battery swapping request corresponding to the battery swapping request includes:

and generating a first password according to the battery swapping request times of the battery swapping request and the current time node.

Optionally, the time node is a date.

Optionally, the generating a battery swap request number corresponding to the battery swap request according to the recently generated battery swap request number includes:

and accumulating 1 for the number of the recently generated battery swapping requests to obtain the number of the battery swapping requests corresponding to the battery swapping requests.

Optionally, the method further includes:

in response to the detection of the networking of the charging cabinet, receiving battery replacement information of at least one user, which is sent by the charging cabinet, wherein the battery replacement information comprises the first password and a battery identifier, and the battery identifier is an identifier of a battery replaced by the charging cabinet in the battery replacement operation;

and determining the battery replaced from the charging cabinet by each user according to the battery replacement information of each user.

Optionally, the method further includes:

and in response to the detection of networking of the charging cabinet, sending one or more battery replacement request times to the charging cabinet, wherein the one or more battery replacement request times are battery replacement request times generated by the server during the network disconnection of the charging cabinet.

Optionally, the method further includes:

deleting the generated times of the power changing request of the charging cabinet at preset time intervals;

and generating the initial battery replacement request times of the charging cabinet.

Optionally, the method further includes:

if the charging cabinet is determined to be in the networking state according to the identifier of the charging cabinet, acquiring the number of the recently generated battery swapping requests of the charging cabinet, and accumulating 1 for the number of the recently generated battery swapping requests to acquire the number of the battery swapping requests corresponding to the battery swapping requests;

and sending a battery swapping instruction to the charging cabinet, wherein the battery swapping instruction is used for indicating the charging cabinet to execute a battery swapping operation.

In a third aspect, the present disclosure provides a charging control device for a charging cabinet, which is applied to the charging cabinet, and the charging control device includes:

the acquisition module is used for responding to the situation that the charging cabinet is in a disconnected network state, and acquiring a first password input by a user, wherein the first password is used for requesting to replace a battery;

the determining module is used for determining a first battery replacement request number for generating the first password according to the first password;

and the processing module is used for executing the battery swapping operation in response to that the target battery swapping request times are not detected or that the first battery swapping request times are different from at least one target battery swapping request times, wherein the target battery swapping request times are the battery swapping request times corresponding to the battery swapping operation executed by the charging cabinet.

Optionally, the apparatus further comprises a generation module;

the generating module is configured to generate corresponding reference passwords according to at least one reference battery replacement request number of times of the charging cabinet before the determining module determines, according to the first password, a first battery replacement request number of times for generating the first password;

the determining module is specifically configured to:

inquiring a reference password according to the first password;

and determining the reference battery swapping request times for generating the target reference password as the first battery swapping request times in response to the fact that the target reference password is the same as the first password.

Optionally, the generating module is specifically configured to:

and respectively generating corresponding reference passwords according to the at least one reference battery replacement request frequency of the charging cabinet and the current time node.

Optionally, the time node is a date.

Optionally, the processing module is further configured to:

after the battery swap operation is executed, the first battery swap request times are marked as target battery swap request times.

Optionally, the processing module is further configured to:

after battery replacement operation is executed, generating battery replacement information of the user, wherein the battery replacement information of the user comprises the first password and a battery identifier, and the battery identifier is an identifier of a battery replaced by the battery replacement operation executed by the charging cabinet;

the device also comprises a sending module;

the sending module is used for responding to the detection of networking of the charging cabinet and sending the battery replacement information of at least one user generated in the network disconnection period of the charging cabinet to a server.

Optionally, the apparatus further comprises: a receiving module;

the receiving module is used for responding to the detection of networking of the charging cabinet and receiving one or more battery replacement request times sent by a server, wherein the one or more battery replacement request times are battery replacement request times generated by the server during the network disconnection period of the charging cabinet;

the processing module is further configured to:

and marking the received one or more battery swapping request times as target battery swapping request times.

Optionally, the receiving module is further configured to respond to the networking of the charging cabinet and receive a battery swapping instruction sent by the server, where the battery swapping instruction is used to instruct the charging cabinet to perform a battery swapping operation;

the processing module is further configured to execute a battery swapping operation according to the battery swapping instruction, acquire the number of battery swapping requests which is recently marked as the target number of battery swapping requests, accumulate 1 for the number of battery swapping requests which is recently marked as the target number of battery swapping requests, acquire the number of battery swapping requests corresponding to the battery swapping instruction, and mark the number of battery swapping requests corresponding to the battery swapping instruction as the target number of battery swapping requests.

Optionally, the apparatus further comprises: a display module;

the display module is further used for responding to the detection of the network disconnection of the charging cabinet before the acquisition module acquires the first password input by the user, and displaying an input interface for requesting to replace the password of the battery;

the obtaining module is specifically configured to:

and acquiring the first password input by the user on the input interface.

Optionally, the processing module is further configured to delete the target power change request number of times of the charging cabinet every preset time interval.

In a fourth aspect, the present disclosure provides a power swapping control device for a charging cabinet, which is applied to a server, and the device includes:

the charging system comprises a receiving module, a charging module and a charging module, wherein the receiving module is used for receiving a battery swapping request sent by terminal equipment of a user, and the battery swapping request comprises an identifier of a charging cabinet;

the acquisition module is used for acquiring the number of times of the recently generated power change request of the charging cabinet if the charging cabinet is determined to be in the network disconnection state according to the identifier of the charging cabinet;

the generation module is used for generating the battery swapping request times corresponding to the battery swapping request according to the recently generated battery swapping request times and generating a first password according to the battery swapping request times corresponding to the battery swapping request;

and the sending module is used for sending the first password to the terminal equipment.

Optionally, the generating module is specifically configured to: and generating a first password according to the times of the battery swapping request and the current time node.

Optionally, the time node is a date.

Optionally, the generating module is specifically configured to: and accumulating 1 for the number of the recently generated battery swapping requests to obtain the number of the battery swapping requests corresponding to the battery swapping requests.

Optionally, the apparatus further comprises: a determination module;

the receiving module is further configured to receive, in response to detecting that the charging cabinet is networked, battery swapping information of at least one user sent by the charging cabinet, where the battery swapping information includes the first password and a battery identifier, and the battery identifier is an identifier of a battery replaced by the charging cabinet executing a battery swapping operation;

the determining module is used for determining the battery replaced from the charging cabinet by each user according to the battery replacement information of each user.

Optionally, the sending module is further configured to send one or more battery replacement request times to the charging cabinet in response to detecting that the charging cabinet is networked, where the one or more battery replacement request times are battery replacement request times generated by the server during a network disconnection period of the charging cabinet.

Optionally, the apparatus further comprises a processing module;

the processing module is used for deleting the generated electricity changing request times of the charging cabinet at preset time intervals and generating initial electricity changing request times of the charging cabinet.

Optionally, the apparatus further comprises:

the acquisition module is further configured to acquire the number of times of the power swapping request of the charging cabinet, which is generated recently, if it is determined that the charging cabinet is in the networking state according to the identifier of the charging cabinet;

the generation module is further configured to accumulate 1 for the number of the battery swapping requests generated recently to obtain the number of the battery swapping requests corresponding to the battery swapping requests;

the sending module is further configured to send a battery swapping instruction to the charging cabinet, where the battery swapping instruction is used to instruct the charging cabinet to perform a battery swapping operation.

In a fifth aspect, the present disclosure provides a charging cabinet, comprising: a memory and a processor;

the memory to store instructions;

the processor invoking the memory-stored instructions for performing the method of the first aspect.

In a sixth aspect, the present disclosure provides a server comprising: a memory and a processor;

the memory to store instructions;

the processor invoking the memory-stored instructions for performing the method of the second aspect.

In a seventh aspect, the present disclosure provides a computer-readable storage medium having stored therein instructions which, when run on a computer, cause the computer to perform the method of the first or second aspect.

In an eighth aspect, the present disclosure provides a computer program product comprising computer instructions that, when executed by a processor, implement the method of the first or second aspect.

By combining the scheme, the battery replacement control method and the battery replacement control device for the charging cabinet can generate the corresponding password according to the number of times of the battery replacement request when the charging cabinet is in the network disconnection state, and the charging cabinet verifies that the password passes through and then executes the battery replacement operation according to the password, so that the charging cabinet can also provide the battery replacement service for a user under the condition that the charging cabinet is in the network disconnection state, the user experience is greatly improved, and the travel requirements of people are met.

Drawings

In order to more clearly illustrate the embodiments of the present disclosure 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 disclosure, and for those skilled in the art, other drawings can be obtained according to the drawings without inventive exercise.

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

fig. 2 is a flowchart of a battery swapping control method of a charging cabinet according to an embodiment of the present disclosure;

fig. 3 is a flowchart of a battery swapping control method for a charging cabinet according to another embodiment of the present disclosure;

fig. 4 is a schematic structural diagram of a battery swapping control device of a charging cabinet according to an embodiment of the present disclosure;

fig. 5 is a schematic structural diagram of a power swapping control device of a charging cabinet according to another embodiment of the present disclosure;

fig. 6 is a schematic structural diagram of a power swapping control device of a charging cabinet according to another embodiment of the present disclosure;

fig. 7 is a schematic structural diagram of a charging control device of a charging cabinet according to another embodiment of the present disclosure;

fig. 8 is a schematic structural diagram of a charging cabinet according to an embodiment of the present disclosure;

fig. 9 is a schematic structural diagram of a server according to an embodiment of the present disclosure.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present disclosure more clear, the technical solutions of the embodiments of the present disclosure will be described clearly and completely with reference to the drawings in the embodiments of the present disclosure, and it is obvious that the described embodiments are some, but not all embodiments of the present disclosure. All other embodiments, which can be derived by a person skilled in the art from the embodiments disclosed herein without making any creative effort, shall fall within the protection scope of the present disclosure.

Under the condition that the charging cabinet is disconnected from the network, the charging cabinet cannot communicate with the server, so that a battery replacement instruction sent by the server cannot be received, and further, battery replacement service cannot be provided for a user. Therefore, the present disclosure provides a power swapping control method and device for a charging cabinet, where the charging cabinet detects that the charging cabinet is in a power-off state, obtains a password input by a user, the charging cabinet determines, according to the password input by the user, the number of power swapping request times for generating the password, and the charging cabinet determines that the number of power swapping request times is the number of power swapping request times for which the charging cabinet does not execute a power swapping operation, and executes the power swapping operation. Therefore, under the condition that the charging cabinet is disconnected, the charging cabinet can provide the battery replacement service for the user.

Fig. 1 is a schematic view of an application scenario provided by an embodiment of the present disclosure, as shown in fig. 1, the scenario includes: terminal equipment 110, server 120, charging cabinet 130, electric bicycle 140. The user sends a battery replacement request to the server 120 through the terminal device 110, when the charging cabinet 130 is disconnected, the server 120 sends a password corresponding to the battery replacement request to the user, the user inputs the password at the charging cabinet 130 to request battery replacement, after the password is verified by the charging cabinet 130 to pass, the charging grid with the full-charge battery is opened, and the user exchanges the under-charge battery in the electric bicycle 140 with the full-charge battery in the charging grid to realize battery replacement of the electric bicycle 140. Terminal device 110 may be any device capable of being communicatively connected to server 120, including but not limited to: a smart phone, a desktop computer, a laptop computer, a tablet computer, a palmtop computer, a wearable device, a virtual reality device, an augmented reality device, and the like, or any combination thereof, as the disclosure is not limited herein. The electric bicycle 140 is, for example, a two-wheeled electric bicycle, but the embodiment is not limited thereto.

In the case of a network failure of the charging cabinet, the following solutions of the embodiments may be referred to for specific implementation processes of the server and the charging cabinet.

Fig. 2 is a flowchart of a power swapping control method for a charging cabinet according to an embodiment of the present disclosure, and as shown in fig. 2, the method of the embodiment may include:

s201, the terminal equipment scans the two-dimensional code of the charging cabinet to obtain the identifier of the charging cabinet.

S202, the server receives a battery swapping request sent by the terminal equipment of the user.

In this embodiment, a user scans a two-dimensional code of the charging cabinet through a camera of the terminal device, where the two-dimensional code is displayed through a display interface of the charging cabinet, for example, to obtain an identifier of the charging cabinet, and then the terminal device sends a battery replacement request to the server. The server receives a battery swapping request sent by terminal equipment of a user, wherein the battery swapping request comprises an identifier of a charging cabinet, and the identifier of the charging cabinet is a group of character strings composed of letters or numbers.

S203, the server responds to the situation that the charging cabinet is in the off-line state according to the identification of the charging cabinet, and the number of times of the recently generated battery replacement request of the charging cabinet is obtained.

In this embodiment, after the server acquires the identifier of the charging cabinet according to the power change request, the server queries the network state of the charging cabinet according to the identifier of the charging cabinet to determine whether the charging cabinet is in a network disconnection state or a network connection state. Specifically, for example: and reporting heartbeat data to the server every 30s by the charging cabinet, if the server cannot acquire the heartbeat data, determining that the charging cabinet is in an off-network state, and otherwise, determining that the charging cabinet is in an on-network state. Under the disconnected state of network, the cabinet that charges and the unable normal communication of server, under the networking state, the cabinet that charges can normal communication with the server.

And after the server determines that the charging cabinet is in the disconnected state, acquiring the number of times of the power switching request of the charging cabinet, which is recently generated by the server. Specifically, for example: if the latest power swapping request is the 10 th power swapping request, the number of the power swapping requests of the charging cabinet generated recently is "10", and 10 also represents the 10 th power swapping request, the server determines that the charging cabinet is in the network disconnection state, and then the number of the power swapping requests of the charging cabinet generated recently is the value "10".

And S204, the server generates a battery swapping request frequency corresponding to the battery swapping request according to the recently generated battery swapping request frequency.

In this embodiment, after the server obtains the number of times of the power swapping request of the charging cabinet generated most recently, the server generates the number of times of the power swapping request corresponding to the power swapping request according to the number of times of the power swapping request of the charging cabinet generated most recently. In a possible implementation manner, the server accumulates the number of battery swapping request times of the charging cabinet generated recently by 1 to obtain the number of battery swapping request times corresponding to the battery swapping request. For example, if the number of battery replacement requests for the charging cabinet generated most recently is "10", the number of battery replacement requests corresponding to the battery replacement request is "11". After the number of times of battery replacement requests corresponding to the battery replacement request is generated, the number of times of battery replacement requests of the charging cabinet generated recently at this time is changed to "11".

And S205, the server generates a first password according to the battery swapping request times corresponding to the battery swapping request.

In this embodiment, after the server generates the number of times of the battery swapping request corresponding to the battery swapping request, the server generates a corresponding password according to the number of times of the battery swapping request corresponding to the battery swapping request, where the password is referred to as a first password.

In a possible implementation manner, the number of the last single digit is calculated and obtained according to the number of times of the battery swapping request corresponding to the battery swapping request by the following algorithm, and the password is composed as an example, taking the password as 5 digits:

first digit of the password: degree 0 x 1+ degree/1 + degree 10

Second bit of the password: times 1 x 2+ times/2 + times 12

Third bit of the password: times 2 x 3+ times/3 + times 14

Fourth digit of password: 3 × 4+ times/4 + times 16

Fifth digit of the password: 4 × 5+ times/5 + times 18

Assuming that the number of times of the battery swapping request corresponding to the battery swapping request is 1, the corresponding password reference is obtained as follows:

first digit of the password: 1+ 0 +1/1+ 10=11.0

Second bit of the password: 1 × 2+1/2+1 × 12=12.5

Third bit of the password: 1, 2, 3+1/3+1, 14=, 20.3

Fourth digit of the password: 1+ 3+ 4+1/4+ 16=16.25

Fifth bit of the password: 1+ 4+ 5+1/5+ 18 + 38.2

The password takes the last one digit number as 12068.

S206, the server sends the first password to the terminal equipment.

In this embodiment, after the server obtains the first password corresponding to the battery swapping request, the server sends the first password to the terminal device. Correspondingly, after the terminal device receives the first password sent by the server, the first password is displayed through a display interface, for example, the first password is displayed through an interface of a charging cabinet Application program (APP) in the terminal device, so that a user can conveniently obtain the first password.

S207, the charging cabinet responds to the fact that the charging cabinet is in the disconnected state, and a first password input by a user is acquired.

In this embodiment, after the user obtains the first password, the user inputs the first password to the charging cabinet. Correspondingly, the charging cabinet responds to the situation that the charging cabinet is detected to be in the off-network state, and the charging cabinet acquires a first password input by a user, wherein the first password is used for requesting to replace the battery.

And S208, the charging cabinet determines the first battery replacement request times for generating the first password according to the first password.

In this embodiment, after the charging cabinet obtains the first password input by the user, the charging cabinet determines, according to the first password, the number of times of battery replacement requests for generating the first password, which is referred to herein as the number of times of the first battery replacement requests.

S209, the charging cabinet responds to the situation that the target battery replacement request times are not detected or the situation that the first battery replacement request times are different from the at least one target battery replacement request times, and battery replacement operation is executed.

In this embodiment, the charging cabinet may be marked with a target battery swapping request number, where the target battery swapping request number is a battery swapping request number corresponding to a battery swapping operation executed by the charging cabinet.

Specifically, the target power swapping request number is, for example, empty, or includes multiple power swapping request numbers. After the charging cabinet determines the first battery replacement request times, the charging cabinet detects the target battery replacement request times according to the first battery replacement request times. If the charging cabinet does not detect the target battery replacement request frequency, the charging cabinet does not mark the battery replacement request frequency as the target battery replacement request frequency, and the charging cabinet is in the current power off state, and the battery replacement operation is not executed, the first battery replacement request frequency is effective, which indicates that a user does not successfully request the battery replacement from the charging cabinet by using a first password generated by the first battery replacement request frequency before, and no password conflict exists, and also indicates that the first password is verified to pass, so that the charging cabinet can execute the battery replacement operation.

If the charging cabinet detects one or more target battery replacement request times, the charging cabinet marks the battery replacement request times as the target battery replacement request times, the charging cabinet executes the battery replacement operation, and then whether the first battery replacement request times is the same as one of the at least one target battery replacement request times is judged. If the first battery replacement request frequency is different from each of the at least one target battery replacement request frequency, it indicates that no user has successfully requested battery replacement from the charging cabinet by using the first password generated by the first battery replacement request frequency before, and no password conflict exists, and it also indicates that the first password passes verification, so that the charging cabinet can execute battery replacement operation. If the first battery replacement request frequency is the same as one of the at least one target battery replacement request frequency, the situation that the user has successfully requested to replace the battery from the charging cabinet by using the first password generated by the first battery replacement request frequency before is indicated, and password conflict exists, so that the charging cabinet does not execute battery replacement operation, for example, the charging cabinet can display information such as 'incorrect password' or 'invalid password' on a display interface.

In the battery swapping control method for the charging cabinet provided in this embodiment, a server receives a battery swapping request sent by a terminal device of a user, generates a number of times of the battery swapping request corresponding to the battery swapping request when the charging cabinet is in a network disconnection state, generates a first password according to the number of times of the battery swapping request, and then sends the first password to the terminal device. The charging cabinet acquires a first password input by a user when being in a network disconnection state, determines a first battery replacement request frequency for generating the first password according to the first password, and executes battery replacement operation if the target battery replacement request frequency is not detected or the first battery replacement request frequency is detected to be different from at least one target battery replacement request frequency. Because this embodiment can be when the cabinet that charges is in the disconnected network state, the server generates corresponding password according to trading electric request number of times, and the cabinet that charges verifies that this password carries out according to this password after passing through trades the electric operation, consequently, under the cabinet that charges condition of netting, the cabinet that charges also can provide for the user trades electric service, has promoted user experience greatly, has satisfied people's trip demand.

Based on the embodiment shown in fig. 2, in some embodiments, fig. 3 is a flowchart of a power swapping control method for a charging cabinet provided in another embodiment of the present disclosure, and as shown in fig. 3, the method of this embodiment includes:

s301, the server receives a battery swapping request sent by the terminal equipment of the user.

S302, the server responds to the fact that the charging cabinet is in the off-line state according to the identification of the charging cabinet, and the number of times of the recently generated battery replacement request of the charging cabinet is obtained.

In this embodiment, the specific implementation processes of S301 and S302 may refer to the related description of the embodiment shown in fig. 2, and are not described herein again.

And S303, the server accumulates the number of the recently generated battery swapping requests by 1 to obtain the number of the battery swapping requests corresponding to the battery swapping requests.

In this embodiment, for example: the number of times of power swapping requests of the charging cabinet generated by the server recently is '10', the server accumulates '10' by 1, and then the number of times of power swapping requests corresponding to the power swapping requests is '11'. After the number of times of power swapping requests corresponding to the power swapping request is generated, the number of times of power swapping requests of the charging cabinet generated by the server most recently at this time is changed to "11". And if the server receives the power change request comprising the identifier of the charging cabinet next time, the number of the power change requests of the charging cabinet which is generated recently and acquired by the server is 11.

After the server obtains the times of the battery swapping requests corresponding to the battery swapping requests, the server generates a first password according to the times of the battery swapping requests corresponding to the battery swapping requests. A specific implementation manner may include S304:

and S304, the server generates a first password according to the battery swapping request times of the battery swapping request and the current time node.

In this embodiment, after the server generates the number of times of the battery swapping request corresponding to the battery swapping request, the server generates a corresponding password according to the number of times of the battery swapping request corresponding to the battery swapping request and the current time node, where the password is referred to as a first password. Because the generated password refers to the current time node, the timeliness of the password is high, the complexity of the password is increased, and the safety is improved.

Optionally, the time node is a date.

In this embodiment, the date is, for example, 7 months and 10 days in 2020. The server calculates and obtains the number of the last unit digit according to the number of battery swapping request times and the current date corresponding to the battery swapping request by the following algorithm, and the number is composed as a password, taking the password as an example of 8 bits:

first digit of the password: number of times 0 x 1+ times/1 + times 10

Second digit of the password: number of times 1 x 2+ times/2 + times 12

Third bit of the password: number of times 2 x 3+ times 14 times

Fourth digit of password: 3 × 4+ times/4 + times 16

Fifth bit of the password: 4 × 5+ times/5 + times 18

Sixth bit of the password: year + number of requested date

Seventh digit of password: month of request date

Eighth bit of the password: date of request

Assuming that the number of times of battery swapping request corresponding to the battery swapping request is 1 and the current date is 2020, 7, month and 10 days, the corresponding password reference is obtained as follows:

first digit of the password: 1+ 0 +1/1+ 10=11.0

Second bit of the password: 1 × 2+1/2+1 × 12=12.5

Third bit of the password: 1 × 2 × 3+1/3+1 × 14=20.3

Fourth digit of password: 1+ 3+ 4+1/4+ 16=16.25

Fifth digit of the password: 1 × 4 × 5+1/5+1 × 18=38.2

Sixth bit of the password: 2020

Seventh digit of the password: 7

Eighth bit of the password: 10

The password takes the last one-digit number as 12068070.

S305, the server sends the first password to the terminal equipment.

In this embodiment, the specific implementation process of S305 may refer to the related description of the embodiment shown in fig. 2, and is not described herein again.

Optionally, the method of this embodiment further includes step S300a:

and S300a, the charging cabinet respectively generates corresponding reference passwords according to at least one reference battery replacement request frequency of the charging cabinet.

In this embodiment, at least one reference power swapping request number is, for example, 100 consecutive numerical values from "1" to "100", the charging cabinet generates a corresponding reference password according to the reference power swapping request number "1", and the charging cabinet generates a corresponding reference password according to the power swapping request number "2", and so on until the charging cabinet generates a corresponding reference password according to the power swapping request number "100". Therefore, the charging cabinet respectively generates 100 corresponding reference passwords according to the 100 reference battery replacement request times of the charging cabinet.

The specific implementation principle of generating the corresponding reference password by the charging cabinet according to each reference battery replacement request number is similar to that of S205, and is not described herein again.

Optionally, an optional implementation manner of the S300a is as follows: and the charging cabinet respectively generates corresponding reference passwords according to at least one reference battery replacement request frequency of the charging cabinet and the current time node. Optionally, the time node is a date. The specific implementation principle is similar to that of S304 described above, and is not described here again.

It should be noted that S300a may be executed when the charging cabinet detects that the charging cabinet is disconnected. Alternatively, S300a may be a preset time interval of the charging cabinet, and the above S300a is performed.

Optionally, this embodiment further includes S300b:

and S300b, the charging cabinet responds to the detected network disconnection of the charging cabinet and displays an input interface of a password for requesting to replace the battery.

In this embodiment, the charging cabinet responds to the situation that the network of the charging cabinet is disconnected, and an input interface for requesting to replace the password of the battery is displayed on a display screen of the charging cabinet, so that a user can conveniently input the password requesting to replace the battery.

In this embodiment, the cabinet that charges just can show foretell input interface after detecting the cabinet that charges and breaking from the net, and the cabinet that charges can not show foretell input interface when detecting the cabinet that charges and networking to avoid user's maloperation, influence user experience.

It should be noted that S300b may be executed before or after S302, and the execution order of S300b and S301 is not limited.

S306, the charging cabinet acquires a first password input by the user on the input interface.

In this embodiment, a user inputs a first password on an input interface of a password displayed on the charging cabinet and used for requesting to replace the battery, and accordingly, the charging cabinet obtains the first password input on the input interface by the user, where the first password is used for requesting to replace the battery.

And S307, the charging cabinet inquires a reference password according to the first password.

In this embodiment, after the charging cabinet acquires the first password, each reference password generated in the step S300a is queried according to the first password.

And S308, in response to the target reference password which is the same as the first password, the charging cabinet determines the reference power swapping request times for generating the target reference password as the first power swapping request times.

In this embodiment, the charging cabinet queries the reference password according to the first password, and if the reference password identical to the first password is queried, the reference password becomes the target reference password. The charging cabinet determines the reference battery swap request times for generating the target reference password as the current battery swap request times of the user according to the target reference password, wherein the battery swap request times is called as a first battery swap request times.

After the step S300a is executed, the charging cabinet may store a mapping relationship between the reference charging times and the reference passwords generated correspondingly, and through the mapping relationship, the charging cabinet may quickly determine the reference battery replacement request times for generating the target reference passwords and also may accurately determine the first battery replacement request times for generating the first passwords.

S309, in response to the situation that the target battery replacement request times are not detected or the situation that the first battery replacement request times are different from the at least one target battery replacement request times are detected, the battery replacement operation is executed by the charging cabinet.

In this embodiment, the target battery swap request number is a number of battery swap requests corresponding to the battery swap operation performed by the charging cabinet. For a specific implementation process of S309, reference may be made to the related description of the embodiment shown in fig. 2, which is not described herein again.

And S310, after the charging cabinet executes the battery swapping operation, marking the first battery swapping request times as target battery swapping request times.

In this embodiment, after the charging cabinet performs the battery swapping operation, the first battery swapping request frequency is marked as the target battery swapping request frequency, which means that the battery swapping request corresponding to the first battery swapping request frequency has successfully performed the battery swapping operation, and if the first password input by the user is obtained again subsequently, and the first battery swapping request frequency is detected through the first password, the battery swapping operation is not performed any more.

And S311, after the charging cabinet executes the battery swapping operation, generating battery swapping information of the user.

In this embodiment, after the charging cabinet executes the battery swapping operation, the battery swapping information of the user is generated. The charging cabinet may also record the generated battery replacement information locally, for example, locally record the battery replacement information of the user in a table manner. The battery replacement information of the user includes a first password and a battery identifier, the battery identifier is an identifier of a battery replaced by the charging cabinet executing the battery replacement operation, and the battery identifier is, for example, a group of character strings composed of letters or numbers.

And S312, the charging cabinet responds to the detection of networking of the charging cabinet, and the charging information of at least one user generated in the network disconnection period of the charging cabinet is sent to the server.

In this embodiment, after the charging cabinet detects that the charging cabinet is networked, the locally recorded battery replacement information of at least one user generated during the network disconnection of the charging cabinet is sent to the server. Correspondingly, after the charging cabinets are networked, the server receives the battery replacement information of at least one user, which is sent by the charging cabinets.

S313, the server determines the battery replaced from the charging cabinet by each user according to the battery replacement information of each user.

In this embodiment, after receiving the battery swapping information of at least one user sent by the charging cabinet, the server matches the password in the battery swapping information of each user with the password locally generated by the server. Taking the example that the battery replacement information comprises a first password, the server judges whether the first password exists in the passwords which are locally generated and used for requesting the charging cabinet to replace the battery, if the first password exists, the fact that the user requests the server to replace the battery exists is indicated, the server determines the corresponding relation among the user, the first password and the battery identification, and therefore the battery which is replaced from the charging cabinet by the user is determined, and resource management of the user using the battery in the charging cabinet is facilitated for the server.

And S314, the server responds to the detection that the charging cabinet is networked, and sends one or more times of battery replacement requests to the charging cabinet.

In this embodiment, after detecting that the charging cabinet is networked, for example, by means of heartbeat, the server sends one or more times of battery replacement requests to the charging cabinet, where the one or more times of battery replacement requests are times of battery replacement requests generated by the server during a period in which the charging cabinet is disconnected from the network. Correspondingly, after the charging cabinets are networked, the charging cabinets receive one or more times of power change requests sent by the server.

And S315, the charging cabinet marks the received one or more battery replacement request times as target battery replacement request times.

In this embodiment, after the charging cabinet receives the one or more battery replacement request times sent by the server, it is described that the one or more battery replacement request times are battery replacement request times generated by the server when the user requests battery replacement during the network disconnection of the charging cabinet, in practical applications, it is possible that the user requests the server for battery replacement to obtain a corresponding password, but the user does not input the corresponding password into the charging cabinet, in order to ensure the real-time performance of the password, avoid the user from reusing the password when the network is disconnected again, and in order to ensure that the target battery replacement request times in the charging cabinet are consistent with the battery replacement request times generated by the server, the server marks the received one or more battery replacement request times as the target battery replacement request times. When the charging cabinet identifies the password subsequently, the password obtained according to the target battery replacement request times is not supported, namely: the passwords corresponding to the target battery replacement request times are invalid. If the user applies for the password from the server during the network disconnection of the charging cabinet, but the password is not input into the charging cabinet for battery replacement during the network disconnection, but is input into the charging cabinet during the next network disconnection of the charging cabinet, the charging cabinet will not execute the battery replacement operation at this moment.

And S316, deleting the target battery replacement request times of the charging cabinet at preset time intervals.

In this embodiment, the preset time period is, for example, 24 hours. For example: and deleting the target battery replacement request times of the charging cabinet at 3 points every morning by the charging cabinet, and correspondingly, all numerical values corresponding to the target battery replacement request times are empty.

And S317, deleting the generated power change request times of the charging cabinet by the server at intervals of preset time length, and generating the initial power change request times of the charging cabinet.

In this embodiment, the preset time period is, for example, 24 hours. For example: the server deletes the generated power change request times of the charging cabinet at 3 am every day, and the initial power change request times of the charging cabinet is generated to be "0", for example. After the server generates the initial power change request times of the charging cabinet, the charging cabinet is disconnected from the network for the first time, and when the server receives the first power change request, the acquired latest generated power change request times are the initial power change request times.

According to the battery replacement control method for the charging cabinet, when the charging cabinet is in the network disconnection state, the server generates the corresponding password according to the battery replacement request times of the user, and the charging cabinet verifies that the password passes through the password and then executes the battery replacement operation, so that the charging cabinet can provide the battery replacement service for the user under the condition that the charging cabinet is in the network disconnection state, user experience is greatly improved, and travel requirements of people are met. In addition, according to the embodiment, when the charging cabinet is in a networking state, the battery replacement information of the user can be synchronized between the charging cabinet and the server, so that resource management of the user using the battery in the charging cabinet can be conveniently performed by the server, and the battery replacement service can be more accurately provided for the user by the times of the battery replacement request generated by the server during the network disconnection of the synchronous charging cabinet between the charging cabinet and the server.

In another embodiment, the terminal device of the user sends a battery swapping request to the server, the battery swapping request includes an identifier of the charging cabinet, and after the server receives the battery swapping request, the server sends a battery swapping instruction to the charging cabinet if the server determines that the charging cabinet is in a networking state according to the identifier of the charging cabinet. Correspondingly, if the charging cabinet is in a networking state, the charging cabinet receives a battery replacement instruction sent by the server, and the battery replacement instruction is used for indicating the charging cabinet to execute a battery replacement operation. The charging cabinet executes the battery swapping operation according to the battery swapping instruction, obtains the battery swapping request times marked as the target battery swapping request times recently, accumulates the battery swapping request times marked as the target battery swapping request times recently by 1, obtains the battery swapping request times corresponding to the battery swapping instruction, and marks the battery swapping request times corresponding to the battery swapping instruction as the target battery swapping request times. Optionally, the charging cabinet responds to that the charging cabinet is in a networking state, the charging cabinet does not display a display interface for inputting a password, and thus the charging cabinet does not acquire the password input by the user, or even if the charging cabinet acquires the password, the battery replacement operation is not executed, but the battery replacement operation is executed after a battery replacement instruction sent by the server.

Optionally, the server responds to a determination that the charging cabinet is in a networked state according to the identifier of the charging cabinet, obtains the number of times of the recently generated power change request of the charging cabinet, and adds 1 to the number of times of the recently generated power change request to obtain the number of times of the power change request corresponding to the power change request. If the charging cabinet is in a networking state, the charging cabinet receives a battery replacement instruction sent by the server, and the charging cabinet accumulates 1 to the maximum value in the target battery replacement request times to obtain a new target battery replacement request time. The counting of the continuous power change request times under the networking and the disconnection of the charging cabinet is realized.

Fig. 4 is a schematic structural diagram of a power swapping control device of a charging cabinet according to an embodiment of the present disclosure, and as shown in fig. 4, a power swapping control device 400 of a charging cabinet according to this embodiment is applied to a charging cabinet, where the power swapping control device 400 of a charging cabinet includes: an acquisition module 401, a determination module 402 and a processing module 403.

The obtaining module 401 is configured to obtain a first password input by a user in response to detection that the charging cabinet is in an off-network state, where the first password is used to request a battery to be replaced;

a determining module 402, configured to determine, according to the first password, a first battery swap request number for generating the first password;

a processing module 403, configured to execute a battery swapping operation in response to that a target battery swapping request number of times is not detected or that the first battery swapping request number of times is different from at least one target battery swapping request number of times, where the target battery swapping request number of times is a battery swapping request number of times that the charging cabinet has executed a battery swapping operation.

The apparatus of this embodiment may be used to implement the technical solution of the charging cabinet in the method embodiment shown in fig. 2, and the implementation principle and the technical effect are similar, which are not described herein again.

Fig. 5 is a schematic structural diagram of a power swapping control device of a charging cabinet according to another embodiment of the present disclosure, and as shown in fig. 5, the power swapping control device 400 of the charging cabinet of this embodiment further includes a generating module 404 on the basis of the embodiment shown in fig. 4.

The generating module 404 is configured to, before the determining module 402 determines, according to the first password, the first power swapping request times for generating the first password, generate corresponding reference passwords according to at least one reference power swapping request time of the charging cabinet.

The determining module 402 is specifically configured to:

inquiring a reference password according to the first password;

and determining the reference battery swapping request times for generating the target reference password as the first battery swapping request times in response to the fact that the target reference password is the same as the first password.

Optionally, the generating module 404 is specifically configured to:

and respectively generating corresponding reference passwords according to the at least one reference battery replacement request frequency of the charging cabinet and the current time node.

Optionally, the time node is a date.

Optionally, the processing module 403 is further configured to:

after the battery swap operation is executed, the first battery swap request times are marked as target battery swap request times.

Optionally, the processing module 403 is further configured to:

after the battery replacement operation is executed, generating battery replacement information of the user, wherein the battery replacement information of the user comprises the first password and a battery identifier, and the battery identifier is an identifier of a battery replaced by the battery replacement operation executed by the charging cabinet;

the apparatus of this embodiment may further include a sending module 405.

The sending module 405 is configured to send, to a server, battery swapping information of at least one user generated during a period in which the charging cabinet is disconnected from the network in response to detecting that the charging cabinet is networked.

Optionally, the apparatus of this embodiment may further include: a receiving module 406.

The receiving module 406 is configured to receive, in response to detecting that the charging cabinet is networked, one or more times of battery replacement requests sent by a server, where the one or more times of battery replacement requests are times of battery replacement requests generated by the server during a network disconnection period of the charging cabinet;

the processing module 403 is further configured to:

and marking the received one or more battery swapping request times as target battery swapping request times.

Optionally, the receiving module 406 is further configured to receive a battery swapping instruction sent by the server in response to the networking of the charging cabinet, where the battery swapping instruction is used to instruct the charging cabinet to perform a battery swapping operation;

the processing module 403 is further configured to execute a battery swapping operation according to the battery swapping instruction, obtain the number of battery swapping requests which is recently marked as the target number of battery swapping requests, add up 1 to the number of battery swapping requests which is recently marked as the target number of battery swapping requests, obtain the number of battery swapping requests corresponding to the battery swapping instruction, and mark the number of battery swapping requests corresponding to the battery swapping instruction as the target number of battery swapping requests.

Optionally, the apparatus of this embodiment further includes: a display module 407.

The display module 407 is further configured to, before the obtaining module 401 obtains the first password input by the user, in response to detecting that the charging cabinet is disconnected from the network, display an input interface of a password for requesting to replace a battery;

the obtaining module 401 is specifically configured to:

and acquiring the first password input by the user on the input interface.

Optionally, the processing module 403 is further configured to delete the target power change request number of the charging cabinet every preset time interval.

The device of this embodiment may be used to implement the technical solutions of the charging cabinets in the above method embodiments, and the implementation principles and technical effects thereof are similar, and are not described herein again.

Fig. 6 is a schematic structural diagram of a power swapping control device of a charging cabinet according to another embodiment of the present disclosure, as shown in fig. 6, the power swapping control device 600 of the charging cabinet according to this embodiment is applied to a server, and the power swapping control device 600 of the charging cabinet includes: a receiving module 601, an obtaining module 602, a generating module 603 and a sending module 604.

The receiving module 601 is configured to receive a battery swapping request sent by a terminal device of a user, where the battery swapping request includes an identifier of a charging cabinet;

an obtaining module 602, configured to obtain a number of times of a power swapping request of the charging cabinet that is generated recently if it is determined that the charging cabinet is in a network disconnection state according to the identifier of the charging cabinet;

a generating module 603, configured to generate a battery swapping request number corresponding to the battery swapping request according to the recently generated battery swapping request number, and generate a first password according to the battery swapping request number corresponding to the battery swapping request;

a sending module 604, configured to send the first password to the terminal device.

The apparatus in this embodiment may be configured to execute the technical solution of the server in the method embodiment shown in fig. 2, and the implementation principle and the technical effect are similar, which are not described herein again.

Fig. 7 is a schematic structural diagram of a power swapping control device of a charging cabinet according to another embodiment of the present disclosure, and as shown in fig. 7, the power swapping control device 600 of the charging cabinet according to this embodiment may further include, on the basis of the embodiment shown in fig. 6: a module 605 is determined.

The receiving module 601 is further configured to receive, in response to detecting that the charging cabinet is networked, battery swapping information of at least one user sent by the charging cabinet, where the battery swapping information includes the first password and a battery identifier, and the battery identifier is an identifier of a battery replaced by the charging cabinet executing a battery swapping operation;

the determining module 605 is configured to determine, according to the battery replacement information of each user, a battery that is replaced from the charging cabinet for each user.

Optionally, the sending module 604 is further configured to send one or more times of battery swapping requests to the charging cabinet in response to detecting that the charging cabinet is networked, where the one or more times of battery swapping requests are times of battery swapping requests generated by the server during a network outage of the charging cabinet.

Optionally, the battery replacement control device 600 of the charging cabinet of this embodiment further includes a processing module 606.

The processing module 606 is configured to delete the generated number of times of the power change request of the charging cabinet at preset time intervals, and generate an initial number of times of the power change request of the charging cabinet.

Optionally, the obtaining module 602 is further configured to obtain the number of times of the power swapping request of the charging cabinet that is generated recently if it is determined that the charging cabinet is in the networking state according to the identifier of the charging cabinet;

the generating module 603 is further configured to accumulate 1 for the number of the recently generated battery swapping requests, so as to obtain the number of the battery swapping requests corresponding to the battery swapping request;

the sending module 604 is further configured to send a battery swapping instruction to the charging cabinet, where the battery swapping instruction is used to instruct the charging cabinet to perform a battery swapping operation.

Optionally, the generating module 603 is specifically configured to: and generating a first password according to the battery swapping request times of the battery swapping request and the current time node.

Optionally, the time node is a date.

Optionally, the generating module 603 is specifically configured to: and accumulating 1 for the number of the recently generated battery swapping requests to obtain the number of the battery swapping requests corresponding to the battery swapping requests.

The apparatus of this embodiment may be configured to execute the technical solutions of the servers in the foregoing method embodiments, and the implementation principles and technical effects are similar, which are not described herein again.

Fig. 8 is a schematic structural diagram of a charging cabinet according to an embodiment of the present disclosure, and as shown in fig. 8, a charging cabinet 800 according to this embodiment may include a memory 801 and a processor 802.

The memory 801 is used for storing instructions;

the processor 802, invoking the memory-stored instructions for performing the following operations:

in response to the fact that the charging cabinet is detected to be in a disconnected state, a first password input by a user is acquired, and the first password is used for requesting to replace a battery;

determining a first battery swap request number for generating the first password according to the first password;

and in response to that the target battery swapping request times are not detected or that the first battery swapping request times are different from at least one target battery swapping request times, executing a battery swapping operation, where the target battery swapping request times are the battery swapping request times corresponding to the battery swapping operation executed by the charging cabinet.

Optionally, before determining, according to the first password, the number of times of the first battery swap request for generating the first password, the processor 802 is further configured to:

respectively generating corresponding reference passwords according to at least one reference battery replacement request frequency of the charging cabinet;

when determining, according to the first password, a first power swapping request number for generating the first password, the processor 802 is specifically configured to:

inquiring a reference password according to the first password;

and determining the reference battery swapping request times for generating the target reference password as the first battery swapping request times in response to the fact that the target reference password is the same as the first password.

Optionally, the processor 802 is specifically configured to:

and respectively generating corresponding reference passwords according to the at least one reference battery replacement request frequency of the charging cabinet and the current time node.

Optionally, the time node is a date.

Optionally, the processor 802 is further configured to mark the first battery swapping request number as a target battery swapping request number after the battery swapping operation is executed.

Optionally, the processor 802 is further configured to:

after battery replacement operation is executed, generating battery replacement information of the user, wherein the battery replacement information of the user comprises the first password and a battery identifier, and the battery identifier is an identifier of a battery replaced by the battery replacement operation executed by the charging cabinet;

and in response to the detection of the networking of the charging cabinet, sending the battery replacement information of at least one user generated during the disconnection of the charging cabinet to a server.

Optionally, the processor 802 is further configured to:

responding to the detection of networking of the charging cabinet, and receiving one or more battery replacement request times sent by a server, wherein the one or more battery replacement request times are battery replacement request times generated by the server during the network disconnection period of the charging cabinet;

and marking the received one or more battery swapping request times as target battery swapping request times.

Optionally, the processor 802 is further configured to:

responding to the networking of the charging cabinets, receiving a battery swapping instruction sent by the server, wherein the battery swapping instruction is used for instructing the charging cabinets to execute a battery swapping operation;

according to the battery swapping instruction, executing a battery swapping operation, obtaining the battery swapping request times which are recently marked as the target battery swapping request times, accumulating the battery swapping request times which are recently marked as the target battery swapping request times by 1, obtaining the battery swapping request times corresponding to the battery swapping instruction, and marking the battery swapping request times corresponding to the battery swapping instruction as the target battery swapping request times.

Optionally, the processor 802 is further configured to, before obtaining the first password input by the user, in response to detecting that the charging cabinet is disconnected from the network, display an input interface of a password for requesting to replace the battery;

when acquiring the first password input by the user, the processor 802 is specifically configured to:

and acquiring the first password input by the user on the input interface.

Optionally, the charging cabinet 800 of this embodiment further includes a display screen (not shown in the figure), and the display screen is used for displaying the input interface.

Optionally, the processor 802 is further configured to:

and deleting the target battery replacement request times of the charging cabinet at preset time intervals.

Optionally, the charging cabinet 800 of the present embodiment further includes a communication device (not shown in the figure) for performing the above-mentioned transceiving operation.

The charging cabinet of this embodiment may be configured to implement the technical solutions of the charging cabinets in the above method embodiments, and the implementation principles and technical effects thereof are similar, and are not described herein again.

Fig. 9 is a schematic structural diagram of a server according to an embodiment of the present disclosure, and as shown in fig. 9, the server 900 according to this embodiment may include: a memory 901 and a processor 902.

The memory 901 is used for storing instructions;

the processor 902, invoking the instructions stored by the memory 901 for performing the following operations:

receiving a battery replacement request sent by terminal equipment of a user, wherein the battery replacement request comprises an identifier of a charging cabinet;

if the charging cabinet is determined to be in the power-off state according to the identifier of the charging cabinet, acquiring the number of recently generated power swapping request times of the charging cabinet, and generating the number of power swapping request times corresponding to the power swapping request according to the number of recently generated power swapping request times;

generating a first password according to the number of times of the battery swapping request corresponding to the battery swapping request;

and sending the first password to the terminal equipment.

Optionally, the processor 902 is specifically configured to:

and generating a first password according to the times of the battery swapping request and the current time node.

Optionally, the time node is a date.

Optionally, the processor 902 is specifically configured to:

and accumulating 1 for the number of the recently generated battery swapping requests to obtain the number of the battery swapping requests corresponding to the battery swapping requests.

Optionally, the processor 902 is further configured to:

in response to the detection of the networking of the charging cabinet, receiving battery replacement information of at least one user, which is sent by the charging cabinet, wherein the battery replacement information comprises the first password and a battery identifier, and the battery identifier is an identifier of a battery replaced by the charging cabinet in the battery replacement operation;

and determining the battery replaced from the charging cabinet by each user according to the battery replacement information of each user.

Optionally, the processor 902 is further configured to:

in response to detecting that the charging cabinet is networked, sending one or more battery swapping request times to the charging cabinet, wherein the one or more battery swapping request times are battery swapping request times generated by the server during the network disconnection of the charging cabinet.

Optionally, the processor 902 is further configured to:

deleting the generated electricity changing request times of the charging cabinet at preset time intervals;

and generating the initial battery replacement request times of the charging cabinet.

Optionally, the processor 902 is further configured to:

if the charging cabinet is determined to be in a networking state according to the identification of the charging cabinet, acquiring the number of times of the recently generated battery replacement request of the charging cabinet, and accumulating 1 for the number of times of the recently generated battery replacement request to acquire the number of times of the battery replacement request corresponding to the battery replacement request;

and sending a battery replacement instruction to the charging cabinet, wherein the battery replacement instruction is used for indicating the charging cabinet to execute a battery replacement operation.

Optionally, the server 902 of this embodiment further includes a communication device (not shown in the figure) for performing the above-mentioned transceiving action.

The server of this embodiment may be configured to execute the technical solutions of the servers in the above method embodiments, and the implementation principles and technical effects are similar, which are not described herein again.

The present disclosure also provides a control system of a charging cabinet, including the charging cabinet provided in any of the above embodiments and a server provided in any of the above embodiments.

The present disclosure also provides a computer program product comprising a computer program which, when executed by a processor, implements the technical solution of the charging cabinet as above.

The present disclosure also provides a computer program product comprising a computer program which, when executed by a processor, implements the technical solution of the server as above.

The present disclosure also provides a computer-readable storage medium, in which computer execution instructions are stored, and when the processor executes the computer execution instructions, the technical solution of the charging cabinet as above is implemented.

The present disclosure also provides a computer-readable storage medium, in which computer program instructions are stored, and when the processor executes the computer program instructions, the technical solution of the above server is implemented.

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.

Finally, it should be noted that: the above embodiments are only used for illustrating the technical solutions of the present disclosure, and not for limiting the same; while the present disclosure has been described in detail with reference to the foregoing embodiments, those of ordinary skill in the art will understand that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications or substitutions do not depart from the scope of the embodiments of the present disclosure by the essence of the corresponding technical solutions.

Claims (21)

1. A battery replacement control method for a charging cabinet is characterized by being applied to the charging cabinet and comprising the following steps:

in response to the fact that the charging cabinet is detected to be in a disconnected state, a first password input by a user is acquired, and the first password is used for requesting to replace a battery;

inquiring a reference password according to the first password, wherein the reference password is a password which is generated according to at least one reference battery replacement request frequency of the charging cabinet and the current time node and corresponds to the reference battery replacement request frequency;

in response to the fact that a target reference password which is the same as the first password is inquired, determining the reference power swapping request times for generating the target reference password as first power swapping request times;

and in response to that the target battery swapping request times are not detected or that the first battery swapping request times are different from at least one target battery swapping request times, executing a battery swapping operation, where the target battery swapping request times are the battery swapping request times corresponding to the battery swapping operation executed by the charging cabinet.

2. The method of claim 1, wherein the time node is a date.

3. The method of claim 1, wherein after the performing the swapping operation, further comprising:

and marking the first power swapping request times as target power swapping request times.

4. The method of claim 1, further comprising:

after battery replacement operation is executed, generating battery replacement information of the user, wherein the battery replacement information of the user comprises the first password and a battery identifier, and the battery identifier is an identifier of a battery replaced by the battery replacement operation executed by the charging cabinet;

and in response to the detection of the networking of the charging cabinet, sending the battery replacement information of at least one user generated during the disconnection of the charging cabinet to a server.

5. The method of claim 1, further comprising:

in response to the detection of the networking of the charging cabinet, receiving one or more battery replacement request times sent by a server, wherein the one or more battery replacement request times are battery replacement request times generated by the server during the network disconnection period of the charging cabinet;

and marking the received one or more battery swapping request times as target battery swapping request times.

6. The method of claim 5, further comprising:

responding to the networking of the charging cabinets, receiving a battery replacing instruction sent by the server, wherein the battery replacing instruction is used for indicating the charging cabinets to execute battery replacing operation;

according to the battery swapping instruction, executing a battery swapping operation, obtaining the battery swapping request times which are recently marked as the target battery swapping request times, accumulating the battery swapping request times which are recently marked as the target battery swapping request times by 1, obtaining the battery swapping request times corresponding to the battery swapping instruction, and marking the battery swapping request times corresponding to the battery swapping instruction as the target battery swapping request times.

7. The method of claim 1, wherein before obtaining the first password entered by the user, further comprising:

in response to detecting that the charging cabinet is disconnected, displaying an input interface for requesting a password for replacing the battery;

the acquiring of the first password input by the user comprises:

and acquiring the first password input by the user on the input interface.

8. The method of any one of claims 1-7, further comprising:

and deleting the target battery replacement request times of the charging cabinet at preset time intervals.

9. A battery replacement control method of a charging cabinet is applied to a server, and the method comprises the following steps:

receiving a battery replacement request sent by terminal equipment of a user, wherein the battery replacement request comprises an identifier of a charging cabinet;

if the charging cabinet is determined to be in the network disconnection state according to the identifier of the charging cabinet, acquiring the number of times of a recently generated battery replacement request of the charging cabinet, and generating the number of times of the battery replacement request corresponding to the battery replacement request according to the number of times of the recently generated battery replacement request;

generating a first password according to the power swapping request times corresponding to the power swapping request and the current time node;

and sending the first password to the terminal equipment.

10. The method of claim 9, wherein the time node is a date.

11. The method of claim 9, wherein the generating a battery swap request number corresponding to the battery swap request according to the most recently generated battery swap request number comprises:

and accumulating 1 for the number of the recently generated battery swapping requests to obtain the number of the battery swapping requests corresponding to the battery swapping requests.

12. The method of claim 9, further comprising:

in response to the detection of the networking of the charging cabinet, receiving battery replacement information of at least one user, which is sent by the charging cabinet, wherein the battery replacement information comprises the first password and a battery identifier, and the battery identifier is an identifier of a battery replaced by the charging cabinet in the battery replacement operation;

and determining the battery replaced from the charging cabinet by each user according to the battery replacement information of each user.

13. The method of claim 9, further comprising:

in response to detecting that the charging cabinet is networked, sending one or more battery swapping request times to the charging cabinet, wherein the one or more battery swapping request times are battery swapping request times generated by the server during the network disconnection of the charging cabinet.

14. The method according to any one of claims 9-13, further comprising:

deleting the generated times of the power changing request of the charging cabinet at preset time intervals;

and generating the initial battery replacement request times of the charging cabinet.

15. The method of claim 9, further comprising:

if the charging cabinet is determined to be in a networking state according to the identification of the charging cabinet, acquiring the number of times of the recently generated battery replacement request of the charging cabinet, and accumulating 1 for the number of times of the recently generated battery replacement request to acquire the number of times of the battery replacement request corresponding to the battery replacement request;

and sending a battery swapping instruction to the charging cabinet, wherein the battery swapping instruction is used for indicating the charging cabinet to execute a battery swapping operation.

16. The utility model provides a trade electric controlling means of cabinet charges which characterized in that, is applied to the cabinet that charges, the device includes:

the acquisition module is used for responding to the situation that the charging cabinet is in a disconnected network state, and acquiring a first password input by a user, wherein the first password is used for requesting to replace a battery;

the determining module is used for inquiring a reference password according to the first password, wherein the reference password is a password which is generated according to at least one reference battery replacement request frequency of the charging cabinet and the current time node and corresponds to the reference battery replacement request frequency; responding to a target reference password which is the same as the first password, and determining the reference battery swapping request times for generating the target reference password as first battery swapping request times;

and the processing module is used for executing the battery swapping operation in response to that target battery swapping request times are not detected or that the first battery swapping request times are different from at least one target battery swapping request times, wherein the target battery swapping request times are the battery swapping request times corresponding to the battery swapping operation executed by the charging cabinet.

17. The utility model provides a trade electric controlling means of cabinet charges which characterized in that, is applied to the server, the device includes:

the charging system comprises a receiving module, a charging module and a charging module, wherein the receiving module is used for receiving a battery swapping request sent by terminal equipment of a user, and the battery swapping request comprises an identifier of a charging cabinet;

the acquisition module is used for acquiring the number of times of the recently generated power change request of the charging cabinet if the charging cabinet is determined to be in the network disconnection state according to the identifier of the charging cabinet;

the generating module is used for generating the battery swapping request times corresponding to the battery swapping request according to the recently generated battery swapping request times, and generating a first password according to the battery swapping request times corresponding to the battery swapping request and the current time node;

and the sending module is used for sending the first password to the terminal equipment.

18. A charging cabinet, comprising: a memory and a processor;

the memory to store instructions;

the processor invoking the memory-stored instructions for performing the method of any of claims 1-8.

19. A server, comprising: a memory and a processor;

the memory to store instructions;

the processor invoking the memory-stored instructions for performing the method of any of claims 9-15.

20. A computer-readable storage medium having stored therein instructions which, when executed on a computer, cause the computer to perform the method of any of claims 1-8 or 9-15.

21. A computer program product comprising computer instructions, characterized in that the computer instructions, when executed by a processor, implement the method of any of claims 1-8 or 9-15.

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