CN115425718A - Storage battery power supplementing method, vehicle and computer readable storage medium - Google Patents

Abstract

The invention discloses a storage battery power supplementing method, a vehicle and a computer readable storage medium. The method comprises the following steps: when the storage battery meets the power supplementing condition, first state data of the vehicle and a first battery state of the storage battery are acquired; judging whether the storage battery meets a preset power supplement early warning rule or not according to the first state data and the first battery state; when the storage battery meets a preset power supplementing rule, the enterprise remote vehicle control platform controls the T-BOX to supplement power to the storage battery according to the first voltage state of the storage battery and judges whether the power supplementing is successful; if the power supply is not successful, second state data of the vehicle and a second battery state of a battery, which are acquired by the T-BOX, are acquired; and re-supplementing the storage battery according to the second state data, the second battery state and the preset power supplementing early warning rule until power supplementing is completed. The invention improves the success rate of automatic power supply.

Description

Storage battery power supplementing method, vehicle and computer readable storage medium

Technical Field

The invention relates to the technical field of vehicle batteries, in particular to a storage battery power supplementing method, a vehicle and a computer readable storage medium.

Background

With the progress of battery power supply technology, batteries are widely applied to industries such as electric automobiles, transformer substations and the like. In such industries, a power supply system for supplying power generally includes a power battery with a higher output voltage and a storage battery with a lower output voltage. Taking a power supply system in an electric automobile as an example, after the power supply system works for a period of time, a power battery in the electric automobile can supplement power for a storage battery, so that the storage battery can be used for a longer time, and necessary electric quantity support is provided for driving.

The scheme of the existing 12V storage battery automatic power supply used by finished automobile enterprises comprises a method for triggering power supply when the voltage of the storage battery is detected to be lower than a threshold value, and a T-BOX automatically analyzes and judges after receiving messages uploaded by each CAN node, and when the voltage of the 12V storage battery is lower than a set threshold value, the automatic power supply of the 12V storage battery is realized. The two methods have the problems of low power supply success rate and low power supply flexibility.

Disclosure of Invention

The invention mainly aims to provide a storage battery power supplementing method, a vehicle and a computer readable storage medium. The problem that the success rate of vehicle power supply is low and the flexibility of power supply is low is solved.

In order to achieve the purpose, the invention provides a storage battery power supplementing method which is applied to a storage battery power supplementing system, wherein the storage battery power supplementing system comprises a T-BOX, an enterprise remote monitoring platform, an enterprise remote early warning platform and an enterprise remote vehicle control platform; the storage battery power supplementing method comprises the following steps:

when the storage battery meets the power supply condition, first state data of the vehicle and a first battery state of the storage battery, which are acquired by the T-BOX, are acquired and uploaded to the enterprise remote monitoring platform;

controlling the enterprise remote early warning platform to judge whether the storage battery meets a preset power supplement early warning rule or not according to the first state data and the first battery state in the enterprise remote monitoring platform, wherein the first battery state comprises a first voltage state;

when the storage battery meets a preset power supplementing rule, the enterprise remote vehicle control platform controls the T-BOX to supplement power to the storage battery according to the first voltage state of the storage battery and judges whether the power supplementing is successful or not;

if the power supply is not successful, second state data of the vehicle and a second battery state of the battery, which are acquired again by the T-BOX, are acquired;

and controlling the enterprise remote early warning platform to perform electricity supplement on the storage battery again according to the second state data, the second battery state and the preset electricity supplement early warning rule until electricity supplement is completed.

Optionally, before the step of acquiring the first state data of the vehicle collected by the T-BOX when the first battery state of the storage battery satisfies the power supply condition, the method further includes:

acquiring the electric quantity state of the storage battery and acquiring the working state of a vehicle CAN network;

the electric quantity state is in a power shortage state, and when the working state is in a wake-up state, the storage battery is judged to meet the power supplement condition.

Optionally, the step of determining, by the control enterprise remote early warning platform according to the first state data and the first battery state, whether the storage battery meets a preset power supply early warning rule includes:

the control enterprise remote early warning platform judges whether the vehicle state condition meets a preset vehicle state condition in a preset power supplement early warning rule or not according to the first state data;

if the preset vehicle state condition is met, determining whether the storage battery meets a power supply interval in a preset power supply early warning rule or not according to the first voltage state;

and if the power supply interval in the preset power supply rule is met, judging that the storage battery meets the preset power supply early warning rule.

Optionally, the step of supplementing power to the storage battery according to the first voltage state of the storage battery, and determining whether power supplementing is successful includes:

determining an initial power supply interval of the storage battery in the preset power supply early warning rule according to the first voltage state of the storage battery;

and supplementing power to the storage battery according to the initial power supplementing interval, and judging whether power supplementing is successful or not.

Optionally, the step of supplementing power to the storage battery according to the initial power supplementing interval, and determining whether power supplementing is successful includes:

controlling the enterprise remote vehicle control platform to send a power supply instruction to the T-BOX and receiving a response instruction of the T-BOX according to the initial power supply interval;

acquiring a finished automobile link state, and judging whether the finished automobile link state is abnormal or not;

and if the response instruction is not received or the link state of the whole vehicle is abnormal, judging that the power supplement is unsuccessful.

Optionally, the preset power supply early warning rule includes a plurality of power supply regions with sequentially decreasing voltages;

and controlling the enterprise remote early warning platform to replenish the power to the storage battery again according to the second state data, the second battery state and the preset power replenishing early warning rule, wherein the step of replenishing the power until the completion of the power replenishment comprises the following steps:

the control enterprise remote early warning platform judges whether the storage battery meets the next second power supply interval of the initial power supply interval or not according to the second state data and the second battery state;

if the second power supply interval is met, power supply is carried out on the storage battery according to the second power supply interval, and whether power supply is successful or not is judged;

and if the power supply is successful, completing the power supply.

Optionally, if a second power supply interval of the initial power supply interval is met, after the step of supplying power to the storage battery according to the second power supply interval and determining whether power supply is successful, the method further includes:

if the power supplement is unsuccessful, selecting the next power supplement interval in the second power supplement interval to execute the steps:

and acquiring second state data of the vehicle and a second battery state of the battery, which are acquired by the T-BOX, until power supplement is successful or the T-BOX cannot receive the power supplement instruction.

Optionally, after the step of determining, by the control enterprise remote early warning platform according to the first state data and the first battery state, whether the storage battery meets a preset power supply early warning rule, the method further includes:

and if the storage battery meets the preset electricity supplementing early warning rule, controlling the remote early warning platform to send out an alarm.

In addition, in order to achieve the above object, the present invention further provides a vehicle including a battery recharging system, a memory, a processor, and a battery recharging program stored on the memory and executable on the processor, wherein the battery recharging program, when executed by the processor, implements the steps of the battery recharging method described above.

In addition, to achieve the above object, the present invention also provides a computer readable storage medium having a battery recharging program stored thereon, which when executed by a processor implements the steps of the battery recharging method as described above.

The invention provides a storage battery power supplementing method, a vehicle and a computer readable storage medium, wherein the storage battery power supplementing method is applied to a storage battery power supplementing system, and the storage battery power supplementing system comprises a T-BOX, an enterprise remote monitoring platform, an enterprise remote early warning platform and an enterprise remote vehicle control platform; the storage battery power supplementing method comprises the following steps: when the first battery state of the storage battery meets the power supplementing condition, first state data of the vehicle acquired by the T-BOX is acquired and uploaded to an enterprise remote monitoring platform; the control enterprise remote early warning platform judges whether the storage battery meets a preset electricity supplementing early warning rule or not according to the first state data and the first battery state, wherein the first battery state comprises a first voltage state; when the storage battery meets a preset power supplementing rule, the enterprise remote vehicle control platform controls the T-BOX to supplement power to the storage battery according to the first voltage state of the storage battery and judges whether the power supplementing is successful or not; if the power supply is not successful, second state data of the vehicle and a second battery state of a battery, which are acquired by the T-BOX, are acquired; and controlling the enterprise remote early warning platform to perform electricity supplement on the storage battery again according to the second state data, the second battery state and the preset electricity supplement early warning rule until electricity supplement is completed. According to the device and the method, a plurality of early warning rules can be set, the success rate of automatic power supply can be ensured, and the vehicle using experience of a user is improved. Through the automatic power supply function, the situation that the user can not start and need rescue due to the insufficient voltage of the 12V storage battery is reduced, the after-sale cost is reduced, and the enterprise benefit is improved. The vehicle can be automatically supplemented by establishing related early warning rules in the enterprise early warning platform in advance and bringing the vehicle into the automatic power supplementing range through the interface, so that all vehicles with hardware capable of realizing automatic power supplementing can be automatically supplemented. The flexibility of the various platform judgment automatic power supply schemes and the characteristic of high success rate of the T-BOX judgment automatic power supply scheme are combined, and the automatic power supply success rate is improved.

Drawings

FIG. 1 is a schematic diagram of an apparatus in a hardware operating environment according to an embodiment of the present invention;

FIG. 2 is a schematic flow chart of an embodiment of a method for replenishing power to a battery according to the present invention;

FIG. 3 is a detailed flowchart of the method for replenishing power to a battery according to an embodiment of the present invention before step S10;

FIG. 4 is a detailed flowchart of step S30 in the method for replenishing power to a storage battery according to an embodiment of the present invention;

fig. 5 is a schematic diagram of a frame structure of the battery recharging system of the invention.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and do not limit the invention.

As shown in fig. 1, fig. 1 is a schematic terminal structure diagram of a hardware operating environment according to an embodiment of the present invention.

The terminal of the embodiment of the invention can be a vehicle.

As shown in fig. 1, the terminal may include: a processor 1001, such as a CPU, a communication bus 1002, a user interface 1003, a dvi interface 1004, a usb interface 1005, and a memory 1006. Wherein a communication bus 1002 is used to enable connective communication between these components. The user interface 1003 may include a Display screen (Display), an input unit such as a Keyboard (Keyboard), and the optional user interface 1003 may also include a standard wired interface, a wireless interface. The DVI interface 1004 may optionally include a standard wired interface to connect with other external devices via DVI wires. The USB interface 1005 may optionally include a standard wired interface for connecting with other external devices via a USB cable. The memory 1006 may be a high-speed RAM memory or a non-volatile memory, such as a disk memory. The memory 1006 may alternatively be a storage device separate from the processor 1001.

Optionally, the terminal may further include an audio circuit and the like, which are not described in detail herein.

Those skilled in the art will appreciate that the terminal structure shown in fig. 1 is not intended to be limiting and may include more or fewer components than those shown, or some components may be combined, or a different arrangement of components.

As shown in fig. 1, the memory 1006, which is a kind of computer storage medium, may include therein an operating system, a DVI interface module, a USB interface module, a user interface module, and a secondary battery charging program.

In the terminal shown in fig. 1, the DVI interface 1004 is mainly used for connecting, and communicating data with, external devices; the USB interface 1005 is mainly used for connecting an external device and performing data communication with the external device; the user interface 1003 is mainly used for connecting a client and performing data communication with the client; and the processor 1001 may be configured to call the battery recharging program stored in the memory 1006, and perform the following operations:

when the storage battery meets the power supply condition, first state data of the vehicle and a first battery state of the storage battery, which are acquired by the T-BOX, are acquired and uploaded to the enterprise remote monitoring platform;

controlling the enterprise remote early warning platform to judge whether the storage battery meets a preset power supplement early warning rule or not according to the first state data and the first battery state in the enterprise remote monitoring platform, wherein the first battery state comprises a first voltage state;

when the storage battery meets a preset power supplementing rule, the enterprise remote vehicle control platform controls the T-BOX to supplement power to the storage battery according to the first voltage state of the storage battery and judges whether the power supplementing is successful or not;

if the power supply is not successful, second state data of the vehicle and a second battery state of the battery, which are acquired again by the T-BOX, are acquired;

and controlling the enterprise remote early warning platform to perform electricity supplement on the storage battery again according to the second state data, the second battery state and the preset electricity supplement early warning rule until electricity supplement is completed.

Further, the processor 1001 may call the battery recharging program stored in the memory 1006, and further perform the following operations:

acquiring the electric quantity state of the storage battery and acquiring the working state of a vehicle CAN network;

the electric quantity state is in a power shortage state, and when the working state is in a wake-up state, the storage battery is judged to meet the power supplement condition.

Further, the processor 1001 may call the battery recharging program stored in the memory 1006, and further perform the following operations:

the control enterprise remote early warning platform judges whether the vehicle state condition meets a preset vehicle state condition in a preset power supplement early warning rule or not according to the first state data;

if the preset vehicle state condition is met, determining whether the storage battery meets a power supply interval in a preset power supply early warning rule or not according to the first voltage state;

and if the power supply interval in the preset power supply rule is met, judging that the storage battery meets the preset power supply early warning rule.

Further, the processor 1001 may call the battery recharging program stored in the memory 1006, and further perform the following operations:

determining an initial power supply interval of the storage battery in the preset power supply early warning rule according to the first voltage state of the storage battery;

and supplementing power to the storage battery according to the initial power supplementing interval, and judging whether power supplementing is successful or not.

Further, the processor 1001 may call the battery recharging program stored in the memory 1006, and further perform the following operations:

controlling the enterprise remote vehicle control platform to send a power supply instruction to the T-BOX and receiving a response instruction of the T-BOX according to the initial power supply interval;

acquiring a finished automobile link state, and judging whether the finished automobile link state is abnormal or not;

and if the response instruction is not received or the link state of the whole vehicle is abnormal, judging that the power supplement is unsuccessful.

Further, the processor 1001 may call the battery recharging program stored in the memory 1006, and further perform the following operations:

the control enterprise remote early warning platform judges whether the storage battery meets the next second power supply interval of the initial power supply interval or not according to the second state data and the second battery state;

if the second power supply interval is met, power supply is carried out on the storage battery according to the second power supply interval, and whether power supply is successful or not is judged;

and if the power supply is successful, completing the power supply.

Further, the processor 1001 may call the battery recharging program stored in the memory 1006, and further perform the following operations:

if the power supplement is unsuccessful, selecting the next power supplement interval in the second power supplement interval to execute the steps:

and acquiring second state data of the vehicle and a second battery state of the battery, which are acquired by the T-BOX, until power supplement is successful or the T-BOX cannot receive the power supplement instruction.

Further, the processor 1001 may call the battery recharging program stored in the memory 1006, and further perform the following operations:

and if the storage battery meets the preset electricity supplementing early warning rule, controlling the remote early warning platform to send out an alarm.

The specific embodiment of the vehicle of the present invention is substantially the same as the following embodiments of the battery recharging process, and will not be described herein again.

Referring to fig. 2, fig. 2 is a schematic flow chart of a battery recharging method according to a first embodiment of the present invention, and the battery recharging method provided in this embodiment includes the following steps:

step S10, when the storage battery meets the power supplementing condition, first state data of the vehicle and first battery state of the storage battery, which are acquired by the T-BOX, are acquired and uploaded to an enterprise remote monitoring platform;

in this embodiment, the recharging condition includes a state of charge of the storage battery and an operating state of the vehicle CAN network. The first battery state includes a first voltage state of the battery, and the first voltage state is a real-time voltage state. The T-BOX is a device which is arranged on a new energy automobile, collects national standard and enterprise self-defined data on the whole automobile through a CAN bus, and wirelessly transmits the data to a remote monitoring platform. The first state data of the vehicle is a vehicle state message acquired by a CAN bus during the power shortage period of the storage battery, and comprises the state message of the storage battery and the like, such as the operation parameters of the storage battery or the driving parameters of the vehicle. After the T-BOX collects the first state data of the vehicle, the first state data is uploaded to an enterprise remote data monitoring platform, and the enterprise remote data monitoring platform analyzes and stores the original message according to a communication protocol.

Specifically, referring to fig. 3, before the step S10, the method further includes:

step S101, acquiring the electric quantity state of the storage battery and acquiring the working state of a vehicle CAN network;

and S102, when the electric quantity state is in a power shortage state and the working state is in a wake-up state, judging that the storage battery meets a power supplement condition.

In the embodiment, the charge state of the storage battery comprises a full charge state and a low charge state, and when the storage battery is in the low charge state, the storage battery needs to be charged. The operating condition of CAN network includes awaken state and dormancy state, only is in the data acquisition that CAN guarantee whole car and the transmission of order when the CAN network is in the awaken state, consequently, only when the CAN network is in the awaken state, CAN guarantee the normal clear of benefit electricity work. Therefore, the storage battery is judged to meet the power supplement condition only when the storage battery is in a power shortage state and the CAN network is in a wake-up state. The power supplementing operation is executed when the storage battery is judged to meet the power supplementing condition, so that the situation that the service life of the storage battery is shortened due to repeated charging when the storage battery is fully charged can be prevented. In addition, when judging whether the battery is in the insufficient voltage state, can also be through obtaining the output current and the output voltage of battery, and according to the output current and the output voltage of battery confirm whether the battery that waits to mend is in the insufficient voltage state, specifically, can obtain according to the output current and the output voltage of battery the output electric charge amount of battery is confirmed whether the output electric charge amount of battery is not less than first preset threshold, if the output electric charge amount of battery is not less than first preset threshold, then the battery is in the insufficient voltage state, if the output electric charge amount of battery is less than first preset threshold, then the battery is not in the insufficient voltage state.

Step S20, controlling an enterprise remote early warning platform to judge whether the storage battery meets a preset electricity supplementing early warning rule or not according to the first state data and the first battery state, wherein the first battery state comprises a first voltage state;

and the enterprise remote early warning platform is in communication connection with the enterprise remote monitoring platform.

Specifically, in an embodiment, the step S20 further includes:

step A21, controlling an enterprise remote early warning platform to judge whether the vehicle state condition meets a preset vehicle state condition in a preset power supplement early warning rule or not according to the first state data;

step A22, if the preset vehicle state condition is met, determining whether the storage battery meets a power supply interval in the preset power supply early warning rule or not according to the first voltage state;

in this embodiment, the preset electricity supplementing early warning rule includes a preset vehicle state condition and a preset electricity supplementing interval, where the vehicle state condition is an accessory condition of electricity supplementing set in a national standard and an enterprise standard, for example, whether a charging robber is inserted into a charging port of a vehicle, or driving data of the vehicle. Those skilled in the art can set different vehicle state conditions according to national standards and enterprise standards to complete the power supplementing operation of the storage battery, and the invention is not limited herein.

The electricity supplementing interval is a voltage interval which is set according to the voltage of the storage battery and is sequentially increased or decreased, for example, the storage battery with 12V may be set to have voltage intervals such as (12V-11V ], (11V-10V ], (10V-9V ], (9V-8V.. Once. (2V-1V), and the like, after the first voltage state of the storage battery, that is, the real-time voltage of the storage battery is detected, the corresponding electricity supplementing interval is found in all the electricity supplementing intervals according to the real-time voltage, for example, if the first voltage state of the storage battery is 11.5V, the corresponding electricity supplementing interval is 12V-11V, and if the first voltage state of the storage battery is 11V, the corresponding electricity supplementing interval is 11V-10V.

Step A23, if the power supply interval in the preset power supply rule is met, judging that the storage battery meets the preset power supply rule;

in this embodiment, when both the vehicle state condition and the first voltage state of the vehicle satisfy the preset power supplement and supplement pre-warning rule, it can be determined that the storage battery satisfies the preset power supplement rule. The present invention is a 12V battery applied to a new energy vehicle, and therefore, when the voltage of the battery is 12V, it can be determined that the preset electricity compensation rule is not satisfied without performing electricity compensation.

Step 30, when the storage battery meets a preset power supply rule, the enterprise remote vehicle control platform controls the T-BOX to supply power to the storage battery according to the first voltage state of the storage battery, and whether power supply is successful is judged;

specifically, the enterprise remote vehicle control platform is connected with the T-BOX, and can issue a remote control instruction to the T-BOX to supplement power for the storage battery.

In an embodiment, referring to fig. 4, the step S30 further includes:

step S31, determining an initial power supply interval of the storage battery in the preset power supply early warning rule according to the first voltage state of the storage battery;

step S32, supplementing power to the storage battery according to the initial power supplementing interval, and judging whether power supplementing is successful;

in the present embodiment, since the voltage of the battery is continuously decreased without the power compensation, the initial power compensation range is matched according to the first voltage state when the battery is first powered. After the initial matching interval is matched, the storage battery can be supplemented, namely, a high-voltage power supplementing instruction on the whole vehicle is sent to the T-BOX by calling a power supplementing interface of an enterprise remote vehicle control platform through the enterprise remote early warning platform, the storage battery is supplemented, and whether power supplementing is successful or not is judged;

specifically, in an embodiment, the step a23 further includes:

step A321, controlling the enterprise remote vehicle control platform to send a power supply instruction to the T-BOX and receive a response instruction of the T-BOX according to the initial power supply interval;

step A322, acquiring a finished automobile link state, and judging whether the finished automobile link state is abnormal or not;

step A323, if the response instruction is not received or the state of the whole vehicle link is abnormal, judging that the power supply is unsuccessful;

in the embodiment, after the power supplement instruction is sent to the T-BOX, the T-BOX feeds back the response instruction to the enterprise remote vehicle control platform to indicate that the T-BOX is in an online state, i.e., the power supplement operation can be performed. The whole vehicle link state comprises a communication link between the enterprise remote monitoring platform and the enterprise remote early warning platform and a communication link between the enterprise remote early warning platform and the enterprise remote vehicle control platform. When the link state of the communication link between the enterprise remote vehicle control platform and the T-BOX is abnormal, namely the link state between the whole vehicle links is abnormal, the power supplement instruction cannot be executed, and the situation of unsuccessful power supplement is caused.

Step S40, if the power supply is not successful, second state data of the vehicle and a second battery state of a battery, which are acquired by the T-BOX, are acquired;

in this embodiment, the second status data is also a vehicle status message collected by the CAN bus during a power shortage period of the storage battery, and includes a status message of the storage battery and the like, for example, an operation parameter of the storage battery, or a driving parameter of the vehicle and the like. The second battery state includes a second voltage state of the battery. Since the charging is unsuccessful, the battery is in a state of continuous power shortage, and the voltage of the battery is decreased and the first state data may be changed compared with the first state data and the first battery state, so that the second state data and the second battery state are the same item of data at different times compared with the first state data and the first battery state.

And S50, controlling the enterprise remote early warning platform to perform electricity supplement on the storage battery again according to the second state data, the second battery state and the preset electricity supplement early warning rule until electricity supplement is completed.

Specifically, in an embodiment, the step S50 further includes:

step A51, controlling an enterprise remote early warning platform to judge whether the storage battery meets a next second power supply interval of the initial power supply interval or not according to the second state data and the second battery state;

in this embodiment, the preset electricity-supplementing warning rule includes a plurality of first decreasing electricity-supplementing intervals, and as described in the above embodiment, since the voltage of the storage battery is gradually decreased, when the electricity is not successfully supplemented in the initial electricity-supplementing interval, and the voltage is decreased to the next electricity-supplementing interval, the electricity-supplementing of the storage battery is triggered again.

Step A52, if the second power supply interval is met, power supply is carried out on the storage battery according to the second power supply interval, and whether power supply is successful is judged;

and step A53, if the power supply is successful, completing the power supply.

In this embodiment, the second power supplement interval and the initial power supplement interval in the above embodiments may be a mark for performing multiple segmented power supplement on the storage battery, that is, each time the voltage of the storage battery reaches one power supplement interval, the automatic power supplement of the storage battery may be automatically triggered, so as to implement multiple power supplement of the storage battery; different power supply strategies during power supply can be realized through different power supply intervals, namely, when the storage battery is in different power supply intervals, different power supply strategies are triggered, for example, when the storage battery is in an initial power supply interval, the voltage is higher, so that the power supply can be performed at a lower voltage; when the storage battery is in other intervals except the initial power supply interval, the voltage of the storage battery is low, so that power can be supplied at high voltage to realize quick power supply of the storage battery.

In an embodiment, after the step a52, the method further includes:

and step A54, if the power supply is unsuccessful. Selecting the next power supplement interval in the second power supplement interval to execute the step S40 until power supplement is successful or the T-BOX cannot receive the power supplement instruction.

In this embodiment, if the second power supplement is not successful, selecting a next power supplement interval adjacent to the second power supplement interval in the preset power supplement early warning rule, continuing to acquire the second state data of the vehicle and the second battery state of the battery, and triggering power supplement again until the power supplement is successful or the T-BOX cannot receive the power supplement instruction. In addition, it should be noted that the enterprise early warning platform can automatically bring into the automatic power supply range after the vehicle is scanned from the production line and is taken off line, and all vehicles with hardware capable of realizing automatic power supply can be ensured to automatically supply power.

The invention provides a storage battery power supplementing method, a vehicle and a computer readable storage medium, wherein the storage battery power supplementing method is applied to a storage battery power supplementing system, and the storage battery power supplementing system comprises a T-BOX, an enterprise remote monitoring platform, an enterprise remote early warning platform and an enterprise remote vehicle control platform; the storage battery power supplementing method comprises the following steps: when the first battery state of the storage battery meets the power supplementing condition, first state data of the vehicle acquired by the T-BOX is acquired and uploaded to an enterprise remote monitoring platform; the control enterprise remote early warning platform judges whether the storage battery meets a preset power supply early warning rule or not according to the first state data and the first battery state, wherein the first battery state comprises a first voltage state; when the storage battery meets a preset power supplementing rule, the enterprise remote vehicle control platform controls the T-BOX to supplement power to the storage battery according to the first voltage state of the storage battery and judges whether the power supplementing is successful or not; if the power supply is not successful, second state data of the vehicle and a second battery state of a battery, which are acquired by the T-BOX, are acquired; and controlling the enterprise remote early warning platform to perform electricity supplement on the storage battery again according to the second state data, the second battery state and the preset electricity supplement early warning rule until electricity supplement is completed. According to the device and the method, a plurality of early warning rules can be set, the success rate of automatic power supply can be ensured, and the vehicle using experience of a user is improved. Through the automatic power supply function, the situation that the user can not start and need rescue due to the insufficient voltage of the 12V storage battery is reduced, the after-sale cost is reduced, and the enterprise benefit is improved. The vehicle automatic power supply method has the advantages that the relevant early warning rules are established on the enterprise early warning platform in advance, and the vehicle is brought into the automatic power supply range through the interface, so that all hardware can automatically supply power to the vehicle. The flexibility of the various platform judgment automatic power supply schemes and the characteristic of high success rate of the T-BOX judgment automatic power supply scheme are combined, and the automatic power supply success rate is improved.

In addition, an embodiment of the present invention further provides a computer-readable storage medium, where a storage battery powering up program is stored on the computer-readable storage medium, and when executed by a processor, the storage battery powering up program implements the following operations:

when the storage battery meets the power supply condition, first state data of the vehicle and a first battery state of the storage battery, which are acquired by the T-BOX, are acquired and uploaded to the enterprise remote monitoring platform;

controlling the enterprise remote early warning platform to judge whether the storage battery meets a preset power supplement early warning rule or not according to the first state data and the first battery state in the enterprise remote monitoring platform, wherein the first battery state comprises a first voltage state;

when the storage battery meets a preset power supplementing rule, the enterprise remote vehicle control platform controls the T-BOX to supplement power to the storage battery according to the first voltage state of the storage battery and judges whether the power supplementing is successful;

if the power supply is not successful, second state data of the vehicle and a second battery state of the battery, which are acquired again by the T-BOX, are acquired;

and controlling the enterprise remote early warning platform to perform electricity supplement on the storage battery again according to the second state data, the second battery state and the preset electricity supplement early warning rule until electricity supplement is completed.

Further, when executed by the processor, the battery recharging program further implements the following operations:

before the step of acquiring the first state data of the T-BOX collected vehicle when the first battery state of the storage battery meets the power supplementing condition, the method further comprises the following steps:

acquiring the electric quantity state of the storage battery and acquiring the working state of a vehicle CAN network;

the electric quantity state is in a power shortage state, and when the working state is in a wake-up state, the storage battery is judged to meet the power supplement condition.

Further, when executed by the processor, the battery recharging program further implements the following operations:

the control enterprise remote early warning platform judges whether the vehicle state condition meets a preset vehicle state condition in a preset power supplement early warning rule or not according to the first state data;

if the preset vehicle state condition is met, determining whether the storage battery meets a power supply interval in a preset power supply early warning rule or not according to the first voltage state;

and if the power supply interval in the preset power supply rule is met, judging that the storage battery meets the preset power supply early warning rule.

Further, when executed by the processor, the battery recharging program further implements the following operations:

determining an initial power supply interval of the storage battery in the preset power supply early warning rule according to the first voltage state of the storage battery;

and supplementing power to the storage battery according to the initial power supplementing interval, and judging whether power supplementing is successful or not.

Further, when executed by the processor, the battery recharging program further implements the following operations:

controlling the enterprise remote vehicle control platform to send a power supply instruction to the T-BOX and receiving a response instruction of the T-BOX according to the initial power supply interval;

acquiring a finished automobile link state, and judging whether the finished automobile link state is abnormal or not;

and if the response instruction is not received or the link state of the whole vehicle is abnormal, judging that the power supplement is unsuccessful.

Further, when executed by the processor, the battery recharging program further implements the following operations:

the control enterprise remote early warning platform judges whether the storage battery meets the next second power supply interval of the initial power supply interval or not according to the second state data and the second battery state;

if the second power supply interval is met, power supply is carried out on the storage battery according to the second power supply interval, and whether power supply is successful or not is judged;

and if the power supplement is successful, completing the power supplement.

Further, when executed by the processor, the battery recharging program further implements the following operations:

if the power supplement is unsuccessful, selecting the next power supplement interval in the second power supplement interval to execute the steps:

and acquiring second state data of the vehicle and a second battery state of the battery, which are acquired by the T-BOX, until power supplement is successful or the T-BOX cannot receive the power supplement instruction.

Further, when executed by the processor, the battery recharging program further implements the following operations:

and if the storage battery meets the preset electricity supplementing early warning rule, controlling the remote early warning platform to send out an alarm.

The specific embodiment of the computer-readable storage medium of the present invention is substantially the same as the embodiments of the battery recharging program, and is not described herein again.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or system. Without further limitation, an element defined by the phrase "comprising a … …" does not exclude the presence of another identical element in a process, method, article, or system that comprises the element.

The above-mentioned serial numbers of the embodiments of the present invention are only for description, and do not represent the advantages and disadvantages of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solution of the present invention may be embodied in the form of a software product, which is stored in a storage medium (e.g., ROM/RAM, magnetic disk, optical disk) as described above and includes instructions for enabling a terminal device (e.g., a mobile phone, a computer, a server, an air conditioner, or a network device) to execute the method according to the embodiments of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. The storage battery power supplementing method is applied to a storage battery power supplementing system, and the storage battery power supplementing system comprises a T-BOX, an enterprise remote monitoring platform, an enterprise remote early warning platform and an enterprise remote vehicle control platform; the storage battery power supplementing method comprises the following steps:

when the storage battery meets the power supply condition, first state data of the vehicle and a first battery state of the storage battery, which are acquired by the T-BOX, are acquired and uploaded to the enterprise remote monitoring platform;

controlling the enterprise remote early warning platform to judge whether the storage battery meets a preset electricity supplementing early warning rule or not according to the first state data and the first battery state in the enterprise remote monitoring platform, wherein the first battery state comprises a first voltage state;

when the storage battery meets a preset power supplementing rule, the enterprise remote vehicle control platform controls the T-BOX to supplement power to the storage battery according to the first voltage state of the storage battery and judges whether the power supplementing is successful;

if the power supply is not successful, second state data of the vehicle and a second battery state of a battery, which are acquired again by the T-BOX, are acquired;

and controlling the enterprise remote early warning platform to perform electricity supplement on the storage battery again according to the second state data, the second battery state and the preset electricity supplement early warning rule until electricity supplement is completed.

2. The battery power-supplementing method of claim 1, wherein before the step of acquiring the first state data of the T-BOX collected vehicle when the first battery state of the battery satisfies the power-supplementing condition, the method further comprises:

acquiring the electric quantity state of the storage battery and acquiring the working state of a vehicle CAN network;

the electric quantity state is in a power shortage state, and when the working state is in a wake-up state, the storage battery is judged to meet the power supplement condition.

3. The storage battery electricity supplementing method of claim 2, wherein the step of judging whether the storage battery meets a preset electricity supplementing early warning rule or not by the control enterprise remote early warning platform according to the first state data and the first battery state comprises the following steps of:

the control enterprise remote early warning platform judges whether the vehicle state condition meets a preset vehicle state condition in a preset power supply early warning rule or not according to the first state data;

if the preset vehicle state condition is met, determining whether the storage battery meets a power supply interval in a preset power supply early warning rule or not according to the first voltage state;

and if the power supply interval in the preset power supply rule is met, judging that the storage battery meets the preset power supply early warning rule.

4. The method for supplementing power to the storage battery according to claim 3, wherein the step of supplementing power to the storage battery according to the first voltage state of the storage battery and judging whether the power supplementing is successful comprises the following steps:

determining an initial power supply interval of the storage battery in the preset power supply early warning rule according to the first voltage state of the storage battery;

and supplementing power to the storage battery according to the initial power supplementing interval, and judging whether the power supplementing is successful or not.

5. The storage battery power supplementing method according to claim 4, wherein the step of supplementing power to the storage battery according to the initial power supplementing interval and judging whether the power supplementing is successful comprises the following steps:

controlling the enterprise remote vehicle control platform to send a power supply instruction to the T-BOX and receiving a response instruction of the T-BOX according to the initial power supply interval;

acquiring a finished automobile link state, and judging whether the finished automobile link state is abnormal or not;

and if the response instruction is not received or the link state of the whole vehicle is abnormal, judging that the power supply is not successful.

6. The storage battery power supplementing method of claim 5, wherein the preset power supplementing early warning rule comprises a plurality of power supplementing intervals with sequentially decreasing voltages;

and controlling the enterprise remote early warning platform to replenish the power to the storage battery again according to the second state data, the second battery state and the preset power replenishing early warning rule, wherein the step of replenishing the power until the completion of the power replenishment comprises the following steps:

the control enterprise remote early warning platform judges whether the storage battery meets the next second power supply interval of the initial power supply interval or not according to the second state data and the second battery state;

if the second power supply interval is met, power supply is carried out on the storage battery according to the second power supply interval, and whether power supply is successful or not is judged;

and if the power supply is successful, completing the power supply.

7. The method for supplementing power to a storage battery according to claim 6, wherein, after the step of supplementing power to the storage battery according to a second power supplementing interval of the initial power supplementing interval and determining whether power supplementing is successful if the second power supplementing interval is satisfied, the method further comprises:

if the power supplement is unsuccessful, selecting the next power supplement interval in the second power supplement interval to execute the steps:

and acquiring second state data of the vehicle and a second battery state of the battery, which are acquired by the T-BOX, until power supplement is successful or the T-BOX cannot receive the power supplement instruction.

8. The method for supplementing power to the storage battery according to claim 7, wherein after the step of judging whether the storage battery meets the preset power supplementing early warning rule or not by the control enterprise remote early warning platform according to the first state data and the first battery state, the method further comprises the following steps:

and if the storage battery meets the preset electricity supplementing early warning rule, controlling the remote early warning platform to send out an alarm.

9. A vehicle, characterized in that it comprises a battery recharging system, a memory, a processor and a battery recharging program stored on said memory and executable on said processor, said battery recharging program, when executed by said processor, implementing the steps of the battery recharging method according to any one of claims 1 to 8.

10. A computer-readable storage medium, having a battery recharging program stored thereon, which, when executed by a processor, implements the steps of the battery recharging method of any of claims 1-8.

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