CN117200407B - Intelligent control method and device for equipment based on BMS - Google Patents

Abstract

The invention discloses a BMS-based intelligent control method and device for equipment, wherein the method comprises the following steps: if the current condition meets a preset control trigger condition, receiving a charge and discharge mode acquisition instruction aiming at the intelligent battery; determining a current battery mode of the intelligent battery according to the charge-discharge mode acquisition instruction, wherein the current battery mode comprises a battery charge mode or a battery discharge mode; and performing a device control operation matched with the current battery mode according to the current battery mode. Therefore, the invention can improve the tracking instantaneity and rationality of the battery mode of the intelligent battery, further improve the determination convenience and determination efficiency of the battery mode of the intelligent battery, and further improve the accuracy and reliability of the determined battery mode of the intelligent battery, thereby improving the execution timeliness and execution reliability of the device control operation, further improving the control efficiency, convenience and accuracy of the device, and further improving the energy use controllability and accuracy of the intelligent battery.

Description

Intelligent control method and device for equipment based on BMS

Technical Field

The invention relates to the technical field of intelligent control, in particular to a device intelligent control method and device based on BMS.

Background

In the application process of the daily battery, most of battery packs and electronic components are in a continuous electric connection state, and the situations that the electronic components are damaged due to the fact that the battery packs are in fault synchronization, the electronic components are suddenly interrupted and do not work due to the fact that the electric quantity of the battery packs is abnormal and the like easily occur, so that the requirements for monitoring the battery and the electronic components electrically connected with the battery packs are continuously improved.

At present, the monitoring mode of the battery and the electronic components electrically connected with the battery is mainly that a worker looks over the electric quantity and the charge and discharge condition of the battery in real time, when the worker artificially discovers that the battery and/or the electronic components are abnormally damaged, the worker is controlled to cut off the power supply and conduct the abnormality processing operation on the battery and/or the electronic components, under the normal condition, when the worker discovers that the battery and/or the electronic components are abnormally damaged by naked eyes, the danger coefficient of the battery and the electronic components is also more than normal, and the control efficiency and the control convenience of the battery and the electronic components are low. It is important to provide a new control method for the device to improve the control efficiency and control convenience of the device (i.e. the battery and the electronic components electrically connected with the battery).

Disclosure of Invention

The technical problem to be solved by the invention is to provide an intelligent control method and device for equipment based on BMS, which can improve the control efficiency and control convenience of the equipment.

In order to solve the technical problems, the first aspect of the present invention discloses a device intelligent control method based on a BMS, the method comprising:

if the current condition meets a preset control trigger condition, receiving a charge and discharge mode acquisition instruction aiming at the intelligent battery;

determining a current battery mode of the intelligent battery according to the charge-discharge mode acquisition instruction, wherein the current battery mode comprises a battery charge mode or a battery discharge mode;

and executing the device control operation matched with the current battery mode according to the current battery mode.

The second aspect of the present invention discloses an intelligent control device for a BMS-based apparatus, the device comprising:

the instruction receiving module is used for receiving a charge and discharge mode acquisition instruction aiming at the intelligent battery if the current condition meets a preset control trigger condition;

the determining module is used for determining a current battery mode of the intelligent battery according to the charge-discharge mode acquisition instruction, wherein the current battery mode comprises a battery charge mode or a battery discharge mode;

And the control module is used for executing equipment control operation matched with the current battery mode according to the current battery mode.

As an alternative embodiment, in the second aspect of the present invention, the apparatus further includes:

the initialization module is used for executing matched power-on initialization operation according to the intelligent battery and the intelligent terminal before the instruction receiving module receives the charge-discharge mode acquisition instruction aiming at the intelligent battery;

and the initialization module specifically comprises the following steps according to the mode of executing matched power-on initialization operation by the intelligent battery and the intelligent terminal:

determining a first application state parameter with a first association relation with an intelligent terminal, and executing a matched first initialization operation on the first application state parameter according to application information of the first application state parameter;

determining a second application state parameter with a second association relation with the intelligent battery, and executing a matched second initialization operation on the second application state parameter according to the application information of the second application state parameter;

and determining a third application state parameter which has a third association relation with the intelligent terminal and the intelligent battery, and executing a matched third initialization operation on the third application state parameter according to the application information of the third application state parameter.

As an alternative embodiment, in the second aspect of the present invention, the apparatus further includes:

the first judging module is used for judging whether the current condition meets a preset control triggering condition according to the determined operation data before the instruction receiving module receives the instruction for acquiring the charge and discharge modes of the intelligent battery; when the judgment result is yes, the instruction receiving module executes the operation of receiving the instruction for acquiring the charge and discharge modes of the intelligent battery;

the instruction generation module is used for generating an interlocking safety processing instruction when the first judgment module judges that the current condition does not meet the control trigger condition;

the control module is further used for executing matched safety processing operation on the intelligent battery and the intelligent terminal according to the interlocking safety processing instruction;

wherein the operation data comprises battery operation data and/or user operation interaction data;

and the first judging module judges whether the current condition meets the preset control triggering condition according to the determined operation data specifically comprises the following steps:

when the determined operation data comprise the battery operation data, judging whether the intelligent battery is in an abnormal state or not according to the battery operation data; when the intelligent battery is judged to be in the abnormal state, determining that the current condition does not meet a preset control triggering condition; when the intelligent battery is judged not to be in the abnormal state, determining that the current condition meets a preset control triggering condition;

When the determined operation data comprise the user operation interaction data, determining an operation instruction matched with the user operation interaction data according to the user operation interaction data; judging whether the operation instruction is in a preset unsafe instruction set or not; when the operation instruction is judged to be in the unsafe instruction set, determining that the current condition does not meet a preset control trigger condition; and when the operation instruction is judged not to be in the unsafe instruction set, determining that the current condition meets a preset control trigger condition.

As an optional implementation manner, in the second aspect of the present invention, the manner in which the control module performs the device control operation matched with the current battery mode according to the current battery mode specifically includes:

if the current battery mode comprises the battery charging mode, determining charging data of the intelligent battery, wherein the charging data comprises charging current data and charging voltage data;

according to the charging data, calculating a charging power result of the intelligent battery, and determining the charging power result as the content to be displayed of a display function module in the intelligent terminal;

Controlling the display function module to execute corresponding display operation based on the content to be displayed;

and/or the number of the groups of groups,

and if the current battery mode comprises the battery charging mode, executing interrupt output operation on other functional modules in the intelligent terminal.

As an optional implementation manner, in the second aspect of the present invention, the manner in which the control module performs the device control operation matched with the current battery mode according to the current battery mode specifically includes:

if the current battery mode comprises the battery discharging mode, determining discharging data of the intelligent battery, wherein the discharging data comprise discharging current data and discharging voltage data;

calculating a discharge power result of the intelligent battery according to the discharge data, and determining the discharge power result as the content to be displayed of a display function module in the intelligent terminal;

controlling the display function module to execute corresponding display operation based on the content to be displayed;

and/or the number of the groups of groups,

if the current battery mode comprises the battery discharging mode, judging whether at least one target functional module which needs to be powered by the intelligent battery except the display functional module exists in the intelligent terminal, and if so, determining all the target functional modules and determining discharging requirement parameters of each target functional module;

And controlling the intelligent battery to execute matched discharging operation on each target functional module based on the discharging demand parameter of each target functional module and the discharging data.

In a second aspect of the present invention, the manner in which the control module controls the display function module to perform the corresponding display operation based on the content to be displayed specifically includes:

monitoring operation instruction data aiming at the display function module, and determining a display mode corresponding to the display function module according to the operation instruction data, wherein the display mode comprises a dormant display mode or a normal display mode;

when the display mode comprises the dormant display mode, controlling the display function module to execute corresponding dormant display operation based on the content to be displayed;

when the display mode comprises the normal display mode, controlling the display function module to execute corresponding normal display operation based on the content to be displayed;

and the control module determines a display mode corresponding to the display function module according to the operation instruction data, wherein the mode specifically comprises the following steps:

determining a target operation instruction associated with the display function module according to the operation instruction data, and determining instruction type information corresponding to the target operation instruction;

Determining instruction time information corresponding to the target operation instruction according to the operation instruction data;

judging whether the target operation instruction meets a preset wake-up control condition according to the instruction type information and the instruction time information;

when the target operation instruction is judged to meet the wake-up control condition, determining that the display mode corresponding to the display function module comprises a conventional display mode;

and when the target operation instruction is judged not to meet the wake-up control condition, determining that the display mode corresponding to the display function module comprises a dormant display mode.

As an alternative embodiment, in the second aspect of the present invention, the apparatus further includes:

the monitoring module is used for monitoring the intelligent battery and real-time status data corresponding to the intelligent terminal when the intelligent terminal and the intelligent battery are determined to be in a normal running state after the control module executes equipment control operation matched with the current battery mode according to the current battery mode;

the determining module is further used for determining the operation conditions corresponding to the intelligent battery and the intelligent terminal according to the real-time condition data;

The second judging module is used for judging whether the intelligent battery meets a preset abnormal processing triggering condition according to the running condition;

the control module is further configured to execute a pause operation control operation on the intelligent terminal when the second judging module judges that the intelligent battery meets the exception handling triggering condition, and execute a matched exception handling operation on the intelligent battery according to the battery condition;

the control module is further used for executing corresponding operation recovery control operation on the intelligent terminal and the intelligent battery when the intelligent battery is detected to meet the preset abnormal processing completion condition;

and the second judging module judges whether the intelligent battery meets the preset abnormal processing triggering condition according to the running condition specifically comprises the following steps:

when the running condition comprises a battery electric quantity condition of the intelligent battery, determining a current electric quantity value of the intelligent battery according to the battery circuit condition; judging whether the current electric quantity value is smaller than or equal to a preset abnormal electric quantity value threshold value or not; when the current electric quantity value is judged to be smaller than or equal to the abnormal electric quantity value threshold value, determining that the intelligent battery meets a preset abnormal processing condition;

When the running condition comprises a function execution condition of the intelligent terminal and the function execution condition is used for indicating that the intelligent terminal is in an interrupt execution state, analyzing the guidance of the intelligent battery and the intelligent terminal in the interrupt execution state according to the real-time condition data; judging whether the guidance quality is larger than or equal to a preset guidance quality threshold value; and when judging that the guidance is larger than or equal to the guidance threshold, determining that the intelligent battery meets a preset abnormal processing condition.

The third aspect of the present invention discloses another intelligent control device for a BMS-based apparatus, which comprises:

a memory storing executable program code;

a processor coupled to the memory;

the processor invokes the executable program code stored in the memory to execute the intelligent control method of the BMS-based device disclosed in the first aspect of the invention.

A fourth aspect of the present invention discloses a computer storage medium storing computer instructions for performing the BMS-based device intelligent control method disclosed in the first aspect of the present invention when the computer instructions are called.

Compared with the prior art, the embodiment of the invention has the following beneficial effects:

in the embodiment of the invention, if the current condition meets the preset control trigger condition, a charge-discharge mode acquisition instruction aiming at the intelligent battery is received; determining a current battery mode of the intelligent battery according to the charge-discharge mode acquisition instruction, wherein the current battery mode comprises a battery charge mode or a battery discharge mode; and performing a device control operation matched with the current battery mode according to the current battery mode. Therefore, compared with the existing equipment control method, the method is beneficial to improving the tracking instantaneity and rationality of the battery mode of the intelligent battery, further beneficial to improving the determination convenience and the determination efficiency of the battery mode of the intelligent battery, further beneficial to improving the accuracy and the reliability of the determined battery mode of the intelligent battery, further beneficial to improving the execution timeliness and the execution reliability of the equipment control operation, further improving the control efficiency, the control convenience and the control accuracy of the equipment, and further beneficial to improving the energy use controllability and the accuracy of the intelligent battery.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic flow diagram of an intelligent control method for a BMS-based device according to an embodiment of the present invention;

fig. 2 is a flow chart of another intelligent control method for a BMS-based device according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of an intelligent control device for a BMS-based apparatus according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of another intelligent control device for a BMS-based device according to an embodiment of the present invention;

fig. 5 is a schematic structural view of another intelligent control device for a BMS-based apparatus according to an embodiment of the present invention;

fig. 6 is a schematic diagram of an intelligent control method of a BMS-based device according to an embodiment of the present invention.

Detailed Description

In order that those skilled in the art will better understand the present invention, a technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in which it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The terms first, second and the like in the description and in the claims and in the above-described figures are used for distinguishing between different objects and not necessarily for describing a sequential or chronological order. Furthermore, the terms "comprise" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion. For example, a process, method, apparatus, article, or article that comprises a list of steps or elements is not limited to only those listed but may optionally include other steps or elements not listed or inherent to such process, method, article, or article.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment may be included in at least one embodiment of the invention. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Those of skill in the art will explicitly and implicitly appreciate that the embodiments described herein may be combined with other embodiments.

The invention discloses an intelligent control method and device for equipment based on a BMS (battery management system), which can determine the current battery mode of an intelligent battery and execute corresponding equipment control operation according to the current battery mode, so that compared with the existing equipment control method, the method is beneficial to improving the tracking instantaneity and rationality of the battery mode of the intelligent battery, further beneficial to improving the determination convenience and determination efficiency of the battery mode of the intelligent battery, further beneficial to improving the accuracy and reliability of the determined battery mode of the intelligent battery, further beneficial to improving the execution timeliness and execution reliability of the equipment control operation, further improving the control efficiency, control convenience and control accuracy of the equipment, and further beneficial to improving the energy use controllability and accuracy of the intelligent battery. The following will describe in detail.

Example 1

Referring to fig. 1, fig. 1 is a flow chart of an intelligent control method for a BMS-based device according to an embodiment of the present invention. The method described in fig. 1 may be applied to a BMS-based device intelligent control apparatus, where the apparatus may include a server, where the server includes a local server or a cloud server, and embodiments of the present invention are not limited. As shown in fig. 1, the intelligent control method of the BMS-based device includes the following operations:

101. and if the current condition meets the preset control trigger condition, receiving a charge and discharge mode acquisition instruction aiming at the intelligent battery.

Optionally, the current condition satisfies a preset control trigger condition, for example: the method and the device for controlling the power-on and power-off of the BMS are capable of achieving normal operation through interaction with BMS communication, namely the current situation meets the preset control triggering condition, and are not limited.

Alternatively, the instruction for acquiring the charge and discharge mode of the intelligent battery may be that the BMS determines the current battery mode of the intelligent battery by detecting the current voltage (such as the charge current voltage and/or the discharge current voltage) of the intelligent battery and sends the current battery mode to the server in the form of the instruction for acquiring the charge and discharge mode, and the server directly determines the current battery mode of the intelligent battery according to the instruction for acquiring the charge and discharge mode; the current and voltage data of the charging and discharging current and voltage of the intelligent battery can be sent to the server in the form of a charging and discharging mode obtaining instruction, the server analyzes the current and voltage data (such as the charging current and voltage data and/or the discharging current and voltage data) in the charging and discharging mode obtaining instruction to determine the current battery mode of the intelligent battery, and the embodiment of the invention is not limited.

Optionally, the instruction for acquiring the charge and discharge mode of the intelligent battery may include current and voltage data (such as charge current and voltage data and/or discharge current and voltage data) of the intelligent battery, information about a current battery mode of the intelligent battery, and other data information capable of determining the current battery mode of the intelligent battery.

102. And determining a current battery mode of the intelligent battery according to the charge and discharge mode acquisition instruction, wherein the current battery mode comprises a battery charge mode or a battery discharge mode.

Optionally, according to the charge-discharge mode obtaining instruction, determining a current battery mode of the intelligent battery, for example: when the charge and discharge mode acquisition instruction comprises information of the current battery mode of the intelligent battery, directly determining the current battery mode of the intelligent battery; further, when the charge-discharge mode obtaining instruction includes current-voltage data of the intelligent battery, the current-voltage data is analyzed to obtain a current battery mode of the intelligent battery, which is not limited by the embodiment of the invention.

Further optionally, the analyzing the current voltage data to obtain the current battery mode of the intelligent battery may include:

Determining a current direction according to the current-voltage data; determining the charging and discharging directions of the intelligent battery according to the current directions; and determining the current battery mode of the intelligent battery according to the charge and discharge directions of the intelligent battery.

Further, when the current direction is the forward direction, the corresponding charging and discharging direction is the charging direction, and the current battery mode of the intelligent battery comprises a battery charging mode; when the current direction is reverse, the corresponding charge-discharge direction is the discharge direction, and the current battery mode of the intelligent battery comprises a battery discharge mode, and the embodiment of the invention is not limited.

103. And performing a device control operation matched with the current battery mode according to the current battery mode.

Optionally, performing a device control operation that matches the current battery mode may include, but is not limited to, controlling the intelligent battery to power the intelligent terminal, charging the intelligent battery in conjunction with the intelligent terminal, electrically controlling an output of the intelligent terminal, controlling an operation of the intelligent terminal, and the like.

Optionally, the device corresponding to the device control operation may include an intelligent battery and/or an intelligent terminal, which is not limited in the embodiment of the present invention; further optionally, as shown in fig. 6, the intelligent battery may be configured with a BMS, the intelligent terminal may include, but is not limited to, a display function module and/or other function modules, further, the display function module may correspond to the LCD display screen in fig. 6, and the other function modules may include, but are not limited to, one or more of a USB/type_c interface, an AC220V charge-discharge interface, an LED lamp, a DC12V interface, a wireless charge interface, and others in fig. 6, further, others may be used to control one or more keys, and the embodiments of the present invention are not limited.

Optionally, the LCD display screen may wake up the backlight of the display screen by long-pressing a 0.5s key, and simultaneously perform interactive display on the current real-time SOC electric quantity of the intelligent battery, the real-time power for input and output, the display on the external enabling function status, and the like, which is not limited in the embodiment of the present invention; and, USB/type_C interface can control USB/type_C discharge interface through the button, USB discharges through 5V, 5A, type_C slowly charges 5V, 5A discharge, charge 20V, 5A discharge fast, forbid discharging according to 0.5s long time, the embodiment of the invention does not limit; the LED lamp can be controlled by enabling the LED lamp to operate in an output mode by long-pressing a 0.5s key, the operation mode 1 is a strong light normal-lighting mode, the operation mode 2 is a weak light normal-lighting mode, the operation mode 3 is an SOS distress signal flashing mode, and the operation stopping mode is disabled by long-pressing for 0.5 s; the DC12V interface can input power supply of the interface in a wide voltage range of 12V-48V and 12A, and the output interface enables discharge control of 12V and 12A for 0.5s and disables discharge for 0.5s, so that the embodiment of the invention is not limited; and the wireless charging interface can discharge according to 5V and 2A, and the embodiment of the invention is not limited; it should be noted that the above values may be set to other values according to practical application requirements, and the embodiment of the present invention is not limited.

Therefore, compared with the existing device control method, the device intelligent control method based on the BMS can be used for determining the current battery mode of the intelligent battery and executing corresponding device control operation according to the current battery mode, and is beneficial to improving tracking instantaneity and rationality of the battery mode of the intelligent battery, further beneficial to improving determination convenience and determination efficiency of the battery mode of the intelligent battery, further beneficial to improving accuracy and reliability of the determined battery mode of the intelligent battery, further beneficial to improving execution timeliness and execution reliability of device control operation, further improving control efficiency, control convenience and control accuracy of the device, and further beneficial to improving energy use controllability and accuracy of the intelligent battery.

In an alternative embodiment, before receiving the instruction for acquiring the charge and discharge mode of the smart battery, the method may further include the following operations:

and executing matched power-on initialization operation according to the intelligent battery and the intelligent terminal.

Optionally, a power-up initialization operation, such as: the power-on initialization configures all application state parameters, triggers the zero clearing of the inter state, configures the application setting parameters, and the like, and the embodiment of the invention is not limited.

Therefore, compared with the existing equipment control method, the power-on initialization function can be provided, the integrity of the equipment control method is improved, influence of historical equipment control operation on current equipment control operation is avoided to a certain extent, and pertinence and accuracy of the current equipment control operation are improved.

In another optional embodiment, the performing the matched power-on initialization operation according to the smart battery and the smart terminal may include:

determining a first application state parameter with a first association relation with the intelligent terminal, and executing a matched first initialization operation on the first application state parameter according to the application information of the first application state parameter;

determining a second application state parameter with a second association relation with the intelligent battery, and executing a matched second initialization operation on the second application state parameter according to the application information of the second application state parameter;

and determining a third application state parameter with a third association relation with the intelligent terminal and the intelligent battery, and executing a matched third initialization operation on the third application state parameter according to the application information of the third application state parameter.

Optionally, a first application state parameter having a first association with the intelligent terminal, for example: LCD screen information, key control flag status bits, data information of other functional modules of the intelligent terminal, terminal operation configuration content of the intelligent terminal and the like.

Optionally, a matched first initialization operation is performed on the first application state parameter, for example: the embodiment of the invention is not limited, and the history information display of the LCD screen is cleared or reset, the key control flag status bit is reset, the data information of other functional modules of the intelligent terminal is cleared or reset, the terminal operation configuration content of the intelligent terminal is cleared or reset, and the like.

Optionally, a second application state parameter having a second association relationship with the smart battery, for example: the BMS communication state detection data, BMS communication state interaction data, historical operation control data of the intelligent battery, battery operation configuration content of the intelligent battery, and the like are not limited by the embodiment of the invention.

Optionally, a matched second initialization operation is performed on a second application state parameter, for example: the embodiment of the invention is not limited, and the BMS historical communication state detection data is cleared or reset, the BMS historical communication state interaction data is cleared or reset, the historical operation control data of the intelligent battery is cleared or reset, the battery operation configuration content of the intelligent battery is cleared or reset, and the like.

Optionally, a third application state parameter having a third association relationship with the intelligent terminal and the intelligent battery, for example: an inter secure state flag bit (corresponding to an Interlock secure processing instruction), an output peripheral control state flag bit, etc., the embodiment of the invention is not limited.

Optionally, a matched third initialization operation is performed on a third application state parameter, illustrating: the embodiment of the invention is not limited by the reset of the inter secure state flag bit, the reset of the output peripheral control state flag bit, and the like.

It can be seen that, this optional embodiment can perform the matched initialization operation on the first application state parameter corresponding to the intelligent terminal, the second application state parameter corresponding to the intelligent battery, and the third application state parameter corresponding to the intelligent terminal and the intelligent battery respectively, which is in favor of improving the comprehensiveness and rationality of the initialization method, and further in favor of improving the comprehensiveness and accuracy of the initialization execution objects (i.e., the first application state parameter, the second application state parameter, and the third application state parameter), and in favor of improving the pertinence, the flexibility, and the execution effectiveness of different initialization operations, thereby being in favor of improving the accuracy and the reliability of the determined initialization result.

In yet another alternative embodiment, the method may further include the following operation before receiving the charge-discharge mode acquisition instruction for the smart battery, which is described above:

judging whether the current condition meets a preset control triggering condition according to the determined operation data;

when the judgment result is yes, executing the operation of receiving the charge and discharge mode acquisition instruction aiming at the intelligent battery;

if the judgment result is negative, generating an interlocking safety processing instruction, and executing matched safety processing operation on the intelligent battery and the intelligent terminal according to the interlocking safety processing instruction;

wherein the operation data comprises battery operation data and/or user operation interaction data.

Alternatively, the user operation interaction data may be understood as: the key mark triggering data of the manual operation control panel further determines that the current condition does not meet the preset control triggering condition when the key mark of the manual operation control panel is used for triggering the inter-lock safety preprocessing command signal, and determines that the current condition meets the preset control triggering condition when the key mark of the manual operation control panel is not used for triggering the inter-lock safety preprocessing command signal, which is not limiting.

Alternatively, the battery operation data may be understood as: when the battery operation data can indicate that the abnormal state of the intelligent battery currently occurs, the current condition is determined to not meet the preset control trigger condition, and when the battery operation data can indicate that the abnormal state of the intelligent battery currently does not occur, the current condition is determined to meet the preset control trigger condition.

Optionally, the Interlock security processing instruction may be understood as an inter-lock security preprocessing command, and further, the inter-lock security preprocessing command is triggered by all security signals in the integrated server, which is not limited in the embodiment of the present invention.

Optionally, according to the interlocking security processing instruction, performing matched security processing operations on the intelligent battery and the intelligent terminal, for example: according to the interlocking safety processing instruction, interrupting the functional output of the intelligent terminal, and carrying out abnormal coping operation on the intelligent battery; further, the abnormality handling operation may be abnormality state processing in which the abnormality is checked and handled by the third-party upper software and the user manually releases the trigger, or the abnormality handling device is controlled to perform the abnormality handling operation on the intelligent battery and to intelligently or manually release the trigger after the abnormality handling operation is performed; further, after the triggered abnormal state is released, the running operation and the control operation which are not completed before the safety processing operation is executed are restored to continue to be executed, and the embodiment of the invention is not limited.

Therefore, compared with the existing equipment control method, the method is beneficial to improving the comprehensiveness and rationality of the equipment control method, further beneficial to improving the control pertinence, flexibility, accuracy and reliability of the equipment, further beneficial to improving the safety processing timeliness and accuracy of the intelligent battery and the intelligent terminal, and can prolong the service lives of the intelligent battery and the intelligent terminal to a certain extent, and effectively prevent the ineffective equipment control operation caused by equipment abnormality.

In still another optional embodiment, the determining, according to the determined operation data, whether the current situation meets the preset control trigger condition may include:

when the determined operation data comprise battery operation data, judging whether the intelligent battery is in an abnormal state according to the battery operation data; when judging that the intelligent battery is in an abnormal state, determining that the current condition does not meet a preset control triggering condition; when judging that the intelligent battery is not in an abnormal state, determining that the current condition meets a preset control triggering condition;

When the determined operation data comprise user operation interaction data, determining an operation instruction matched with the user operation interaction data according to the user operation interaction data; judging whether the operation instruction is in a preset unsafe instruction set or not; when the operation instruction is judged to be in the unsafe instruction set, determining that the current condition does not meet the preset control trigger condition; and when the operation instruction is judged not to be in the unsafe instruction set, determining that the current condition meets the preset control trigger condition.

Further optionally, the determining, according to the battery operation data, whether the intelligent battery is in an abnormal state may include:

analyzing the real-time change condition of the operation parameters of the intelligent battery according to the battery operation data;

judging whether the real-time change condition is matched with the expected change condition of the preset operation parameters;

when the judgment result is yes, determining that the intelligent battery is not in an abnormal state;

and when the judgment result is negative, determining that the intelligent battery is in an abnormal state.

Alternatively, the operation parameter of the intelligent battery may be any battery parameter related to the operation condition of the intelligent battery, and may also be understood as any battery parameter capable of reflecting whether an abnormal condition occurs in the intelligent battery, which is not limited by the embodiment of the present invention.

Optionally, the user operation interaction data, the operation instruction and the unsafe instruction set may be understood as: whether the user has a key mark used for triggering and generating the inter-lock safety preprocessing command signal in the artificial operation panel or not is judged, namely whether the user has the function of triggering and generating the inter-lock safety preprocessing command signal through keys or not is judged, and the embodiment of the invention is not limited.

It can be seen that this alternative embodiment is capable of determining that the control trigger condition is satisfied by analyzing the battery running state or analyzing the user operation interaction instruction, and thus, is advantageous to improve the diversity, flexibility and comprehensiveness of the control trigger condition satisfaction determining method compared with the existing device control method, and further, the accuracy and the reliability of the determined control trigger condition meeting conditions are improved, thereby improving the equipment control timeliness and the efficiency aiming at the control trigger condition meeting conditions.

In still another alternative embodiment, the performing the device control operation matched with the current battery mode according to the current battery mode may include:

If the current battery mode comprises a battery charging mode, determining charging data of the intelligent battery, wherein the charging data comprise charging current data and charging voltage data;

according to the charging data, calculating a charging power result of the intelligent battery, and determining the charging power result as the content to be displayed of a display function module in the intelligent terminal;

controlling the display function module to execute corresponding display operation based on the content to be displayed;

and/or the number of the groups of groups,

and if the current battery mode comprises a battery charging mode, executing interrupt output operation on other functional modules in the intelligent terminal.

Optionally, the charging power of the intelligent battery may be tracked in real time, the charging power display control operation of the intelligent battery may be performed when the charging power display instruction is detected, and the charging power calculation control operation of the intelligent battery may be performed when the charging power determination instruction is detected.

Optionally, the above-mentioned executing an interrupt output operation on other functional modules in the intelligent terminal, for example: the embodiment of the invention is not limited by controlling the operation function output of other functional modules in the intelligent terminal to be invalid, controlling the intelligent battery not to supply power to other functional modules in the intelligent terminal, and the like.

In the above optional embodiment, further optionally, if the current battery mode includes a battery charging mode, the controlling the display function module to execute the corresponding display operation based on the content to be displayed may include:

monitoring operation instruction data aiming at the display function module, and determining a display mode corresponding to the display function module according to the operation instruction data, wherein the display mode comprises a dormant display mode or a conventional display mode;

when the display mode comprises a dormant display mode, controlling the display function module to execute corresponding dormant display operation based on the content to be displayed;

when the display mode includes a normal display mode, the display function module is controlled to execute a corresponding normal display operation based on the content to be displayed.

It should be noted that, for other descriptions of the present alternative embodiment, please refer to the following detailed description of the "control the display function module to perform the corresponding display operation based on the content to be displayed", and the embodiments of the present invention are not repeated.

In the above optional embodiment, further optionally, if the current battery mode includes a battery charging mode, determining, according to the operation instruction data, a display mode corresponding to the display function module may include:

Determining a target operation instruction associated with the display function module according to the operation instruction data, and determining instruction type information corresponding to the target operation instruction;

determining instruction time information corresponding to a target operation instruction according to the operation instruction data;

judging whether the target operation instruction meets a preset wake-up control condition according to the instruction type information and the instruction time information;

when the target operation instruction is judged to meet the wake-up control condition, determining that the display mode corresponding to the display function module comprises a conventional display mode;

and when the target operation instruction is judged not to meet the wake-up control condition, determining that the display mode corresponding to the display function module comprises a dormant display mode.

It should be noted that, for other descriptions of the optional embodiment, please refer to the following detailed description of "determining the display mode corresponding to the display function module according to the operation instruction data", and the embodiments of the present invention are not repeated.

It can be seen that, this optional embodiment can provide corresponding and specific device control operations for the case that the current battery mode includes the battery charging mode, further, the device control operations include display operations of the display function module and/or interrupt output operations of other function modules, which is favorable to improving pertinence and flexibility of the device control operations, and further is favorable to improving execution rationality and execution accuracy of the device control operations, and in addition, can also monitor and display charging conditions (such as charging power) of the intelligent battery in real time, is favorable to improving charging condition monitoring instantaneity, viewing efficiency and convenience of the intelligent battery, and further is favorable to improving timeliness of coping with charging abnormality of the intelligent battery and safety reliability of charging use of the intelligent battery.

In still another alternative embodiment, the performing the device control operation matched with the current battery mode according to the current battery mode may include:

if the current battery mode comprises a battery discharging mode, determining discharging data of the intelligent battery, wherein the discharging data comprise discharging current data and discharging voltage data;

according to the discharge data, calculating a discharge power result of the intelligent battery, and determining the discharge power result as the content to be displayed of a display function module in the intelligent terminal;

controlling the display function module to execute corresponding display operation based on the content to be displayed;

and/or the number of the groups of groups,

if the current battery mode comprises a battery discharging mode, judging whether at least one target functional module which needs to be powered by the intelligent battery except the display functional module exists in the intelligent terminal, and if so, determining all the target functional modules and determining discharging requirement parameters of each target functional module;

and controlling the intelligent battery to execute matched discharging operation on each target functional module based on the discharging demand parameters and the discharging data of each target functional module.

Alternatively, the discharge power of the intelligent battery may be tracked in real time, the discharge power display control operation of the intelligent battery may be performed when the discharge power display instruction is detected, and the discharge power calculation control operation of the intelligent battery may be performed when the discharge power determination instruction is detected.

Optionally, the above-mentioned control intelligent battery performs a matched discharging operation for each target function module, for example: after determining that the current battery mode includes the battery discharging mode, controlling the intelligent battery to supply power to each target functional module (namely, controlling the target functional module to operate and output), and further controlling the target functional module to operate according to the determined required operation mode according to actual requirements, wherein the embodiment of the invention is not limited.

It can be seen that, this optional embodiment can provide corresponding and specific device control operations to the condition that current battery mode includes battery discharge mode, further, this device control operations includes the display operation of display function module and/or the discharge operation of intelligent battery, in this way, compare in current device control method, be favorable to improving pertinence and flexibility of device control operation, and then be favorable to improving the execution rationality and the execution accuracy of device control operation, in addition, can also monitor and display the discharge situation (such as discharge power) of intelligent battery in real time, can also be favorable to improving the discharge situation monitoring instantaneity, view efficiency and convenience of intelligent battery, and then be favorable to improving the security reliability of handling timeliness and intelligent battery discharge use of abnormal intelligent battery, in addition, can also control the intelligent battery to discharge to the target function module that needs to supply power, in addition, be favorable to improving intelligent battery discharge accuracy and discharge adaptation, and then be favorable to intelligent battery energy-conservation and reduce loss, in addition, can also be favorable to improving the control independence, pertinence and accuracy to different function modules that intelligent terminal includes.

In an optional embodiment, the controlling the display function module to perform the corresponding display operation based on the content to be displayed may include:

monitoring operation instruction data aiming at the display function module, and determining a display mode corresponding to the display function module according to the operation instruction data, wherein the display mode comprises a dormant display mode or a conventional display mode;

when the display mode comprises a dormant display mode, controlling the display function module to execute corresponding dormant display operation based on the content to be displayed;

when the display mode includes a normal display mode, the display function module is controlled to execute a corresponding normal display operation based on the content to be displayed.

Optionally, the operation instruction data and the display mode corresponding to the display function module are illustrated by: when the running instruction data is used for indicating that no other control operation exists, the LCD display screen (i.e. the display function module) does not display other data, any key instruction capable of waking up the LCD display screen is not triggered, and the like, the LCD display screen is in a dormant display mode immediately or after a set time period (such as after one minute or after the other minutes); further, the display mode of the display function module can be a conventional display mode by triggering any key instruction capable of waking up the LCD display screen, that is, when the LCD display screen is currently in the sleep display mode, triggering any key instruction capable of waking up the LCD display screen can enable the display mode of the LCD display screen to be converted into the conventional display mode, and when the LCD display screen is currently in the conventional display mode, triggering any key instruction capable of waking up the LCD display screen can enable the LCD display screen to maintain the conventional display mode.

Optionally, the controlling display function module based on the content to be displayed performs a corresponding sleep display operation, for example: the display function module is controlled to be in a normal low-power standby state (such as low-brightness display or screen extinction), further, the content to be displayed can be updated in real time or updated when the display requirement is received, and the embodiment of the invention is not limited.

Optionally, the above-mentioned control display function module performs a corresponding conventional display operation based on the content to be displayed, for example: the display function module updates and displays the content to be displayed in real time according to conventional power consumption (such as conventional brightness display), and the embodiment of the invention is not limited.

Therefore, compared with the existing equipment control method, the display mode diversity and flexibility of the display function module are improved, display intellectualization, display pertinence and display diversity of the display function module are improved, execution accuracy and execution pertinence of display control operation are improved, and energy consumption of the display function module is reduced to a certain extent.

In an optional embodiment, the determining, according to the operation instruction data, the display mode corresponding to the display function module may include:

determining a target operation instruction associated with the display function module according to the operation instruction data, and determining instruction type information corresponding to the target operation instruction;

determining instruction time information corresponding to a target operation instruction according to the operation instruction data;

judging whether the target operation instruction meets a preset wake-up control condition according to the instruction type information and the instruction time information;

when the target operation instruction is judged to meet the wake-up control condition, determining that the display mode corresponding to the display function module comprises a conventional display mode;

and when the target operation instruction is judged not to meet the wake-up control condition, determining that the display mode corresponding to the display function module comprises a dormant display mode.

Optionally, the instruction type information is an instruction capable of determining whether the target execution instruction is a command triggering the display function module to be in a normal display mode, further illustrating: when other control operations exist, other data need to be displayed on the LCD display screen (i.e. the display function module), a conventional display trigger instruction correspondingly exists when any key instruction capable of waking up the LCD display screen is received, and when the instruction type of the target operation instruction is matched with the instruction type of the conventional display trigger instruction, the target operation instruction is determined to meet the preset wake-up control condition, that is, the display function module is determined to be in the conventional display mode.

Further alternatively, instruction time information, such as: for example, when the instruction time information is used for indicating that the display function module enters a sleep state after 1 minute, the display mode of the display function module is a sleep display mode; for example, when the instruction time information is used for indicating that the sleep display mode is continuously maintained for the next 5 minutes, the display function module is in the sleep display mode; for example, when the instruction time information is used to indicate that the display function module is dormant after 2 minutes, the display function module is in a normal display mode, and other conditions are similarly available, which is not repeated here.

Optionally, according to the instruction type information and the instruction time information, whether the target operation instruction meets a preset wake-up control condition is judged, for example: the LCD screen does not display other data states, does not receive any key instruction triggering the LCD screen to wake up, and the like, and the LCD screen (namely the display function module) enters a dormant state after 1 minute; further, when a wake-up instruction generated by triggering any key by the user is detected or any instruction capable of waking up the LCD display screen is received, the display function of the LCD display screen is waken up, that is, the display mode of the display function module is controlled to be a conventional display mode, and the embodiment of the invention is not limited.

Therefore, compared with the existing equipment control method, the method is beneficial to improving the rationality and the basis of the display mode determining method of the display function module, and further is beneficial to improving the accuracy and the reliability of the determined display mode.

Example two

Referring to fig. 2, fig. 2 is a flow chart of another intelligent control method for a BMS-based device according to an embodiment of the present invention. The method described in fig. 2 may be applied to a BMS-based device intelligent control apparatus, where the apparatus may include a server, where the server includes a local server or a cloud server, and embodiments of the present invention are not limited. As shown in fig. 2, the BMS-based device intelligent control method includes the following operations:

201. and if the current condition meets the preset control trigger condition, receiving a charge and discharge mode acquisition instruction aiming at the intelligent battery.

202. And determining a current battery mode of the intelligent battery according to the charge and discharge mode acquisition instruction, wherein the current battery mode comprises a battery charge mode or a battery discharge mode.

203. And performing a device control operation matched with the current battery mode according to the current battery mode.

204. When the intelligent terminal and the intelligent battery are determined to be in the normal running state, the real-time condition data corresponding to the intelligent battery and the intelligent terminal are monitored, and the running conditions corresponding to the intelligent battery and the intelligent terminal are determined according to the real-time condition data.

Optionally, the intelligent terminal and the intelligent battery are in a normal running state, which can be understood as follows: the intelligent terminal and the intelligent battery are performing corresponding operation according to the equipment control instruction of the server, and the embodiment of the invention is not limited.

205. And judging whether the intelligent battery meets a preset abnormal processing triggering condition according to the running condition.

Further optionally, when it is determined that the intelligent battery does not meet the abnormal processing triggering condition, the monitoring of the real-time condition data corresponding to the intelligent battery and the intelligent terminal is performed, and the operation conditions corresponding to the intelligent battery and the intelligent terminal are determined according to the real-time condition data; according to the operation condition, whether the intelligent battery meets the operation of the preset abnormal processing triggering condition is judged, and the embodiment of the invention is not limited.

206. And when judging that the intelligent battery meets the abnormal processing triggering condition, executing the operation suspension control operation on the intelligent terminal, and executing the matched abnormal processing operation on the intelligent battery according to the battery condition.

Further optionally, the performing the matched exception handling operation on the intelligent battery according to the battery condition may include:

performing a pause charge and discharge operation on the battery mode;

determining the abnormal type and specific abnormal condition of the intelligent battery according to the battery condition, and determining the abnormal treatment measure of the intelligent battery according to the abnormal type and specific abnormal condition;

and executing matched exception handling operation on the intelligent battery according to the exception handling measures.

Further optionally, the performing, by the third party exception handling device, the matched exception handling operation on the intelligent battery according to the exception handling measure may be checking and handling, by the third party exception handling device, an exception condition of the intelligent battery, and further performing, by the user, exception handling by manually releasing a trigger, or performing, by the server, exception handling on the intelligent battery directly.

In the embodiment of the present invention, for other descriptions of step 201 to step 206, please refer to other detailed descriptions of step 101 to step 103 in the first embodiment, and the description of the embodiment of the present invention is omitted.

Therefore, compared with the existing equipment control method, the method is beneficial to improving the tracking instantaneity and rationality of the battery mode of the intelligent battery, further beneficial to improving the determination convenience and determination efficiency of the battery mode of the intelligent battery, further beneficial to improving the accuracy and reliability of the determined battery mode of the intelligent battery, further beneficial to improving the execution timeliness and execution reliability of the equipment control operation, further improving the control efficiency, control convenience and control accuracy of the equipment, and further beneficial to improving the energy use controllability and accuracy of the intelligent battery; and the method for triggering and monitoring the abnormal processing of the intelligent battery can also be provided, when the intelligent battery is judged to meet the triggering condition of the abnormal processing, corresponding control operation is executed on the intelligent terminal and the intelligent battery, so that compared with the existing equipment control method, the method is beneficial to improving the operation monitoring instantaneity and the abnormal processing timeliness of the intelligent battery and the intelligent terminal, and further beneficial to improving the operation stability and the operation reliability of the intelligent battery and the intelligent terminal, thereby being beneficial to improving the accuracy, the safety and the reliability of equipment control.

In an alternative embodiment, the method may further comprise the operations of:

when the intelligent battery is detected to meet the preset abnormal processing completion condition, corresponding operation recovery control operation is executed on the intelligent terminal and the intelligent battery.

Optionally, the intelligent battery meets a preset condition for completing the exception handling, which can be understood as that the exception handling operation of the intelligent battery is completed, the intelligent battery does not have an exception currently, the exception of the intelligent battery has been resolved, and the like.

Optionally, the above-mentioned executing a corresponding operation control operation for recovering the intelligent terminal and the intelligent battery, for example: the intelligent terminal and the intelligent battery are controlled to continue to operate according to the operation mode before the exception handling operation is executed, and the embodiment of the invention is not limited.

Therefore, compared with the existing equipment control method, the integrity and rationality of the equipment control method and the exception handling method of the intelligent battery are improved, and further the exception handling reliability and rationality of the intelligent battery and the intelligent terminal are improved.

In another optional embodiment, the determining, according to the operation condition, whether the intelligent battery meets the preset exception handling triggering condition may include:

when the running condition comprises the battery electric quantity condition of the intelligent battery, determining the current electric quantity value of the intelligent battery according to the battery circuit condition; judging whether the current electric quantity value is smaller than or equal to a preset abnormal electric quantity value threshold value or not; when the current electric quantity value is judged to be smaller than or equal to the abnormal electric quantity value threshold value, determining that the intelligent battery meets a preset abnormal processing condition;

when the running condition comprises the function execution condition of the intelligent terminal and the function execution condition is used for indicating that the intelligent terminal is in an interrupt execution state, analyzing the guidance of the intelligent battery and the intelligent terminal in the interrupt execution state according to the real-time condition data; judging whether the guidance quality is larger than or equal to a preset guidance quality threshold value; and when judging that the guidance quality is greater than or equal to the guidance quality threshold value, determining that the intelligent battery meets the preset abnormal processing condition.

Optionally, the determining whether the current electric quantity value is less than or equal to the preset abnormal electric quantity value threshold may be understood as determining whether the intelligent battery is currently in a low electric quantity state, that is, performing low electric quantity protection on the intelligent battery, which is not limited by the embodiment of the present invention.

Optionally, the determining whether the guidance is greater than or equal to the preset guidance threshold may be understood as determining whether the intelligent terminal is interrupted due to an abnormal state of the intelligent battery, that is, determining whether the intelligent terminal is interrupted due to the reason of the intelligent battery, which is not limited by the embodiment of the present invention.

Optionally, the guidance of the state of interrupt execution of the intelligent battery and the intelligent terminal may be understood as the relevance of the interrupt execution of the intelligent battery and the intelligent terminal, that is, how much responsibility the intelligent battery occupies for the situation that the intelligent terminal is interrupt executed, which is not limited by the embodiment of the present invention.

Further optionally, when the current electric quantity value is determined to be greater than the abnormal electric quantity value threshold, it is determined that the intelligent battery does not meet a preset abnormal processing condition, and the embodiment of the invention is not limited.

Further optionally, when the guidance is determined to be less than the guidance threshold, it is determined that the intelligent battery does not meet a preset abnormal processing condition, and the embodiment of the invention is not limited.

Further optionally, the determining, according to the operation condition, whether the intelligent battery meets a preset abnormal processing triggering condition may include:

when the running condition comprises the battery electric quantity condition of the intelligent battery, determining a used electric quantity value of the intelligent battery according to the battery circuit condition;

Judging whether the used electric quantity value is larger than or equal to a preset used electric quantity value threshold value or not;

when the used electric quantity value is judged to be greater than or equal to the used electric quantity value threshold value, determining that the intelligent battery meets a preset abnormal processing condition;

and when the used electric quantity value is judged to be smaller than the used electric quantity value threshold value, determining that the intelligent battery meets the preset abnormal processing condition.

Therefore, compared with the existing equipment control method, the method is beneficial to improving the comprehensiveness, rationality and flexibility of the method for determining the abnormal processing condition satisfaction condition, and further is beneficial to improving the accuracy and reliability of the determined abnormal processing condition satisfaction condition, so that the timeliness of abnormal discovery and abnormal processing of the intelligent battery are beneficial to improving.

Example III

Referring to fig. 3, fig. 3 is a schematic structural diagram of an intelligent control device for a BMS-based apparatus according to an embodiment of the present invention. The apparatus described in fig. 3 may include a server, where the server includes a local server or a cloud server, and embodiments of the present invention are not limited. As shown in fig. 3, the BMS-based device intelligent control apparatus may include:

The instruction receiving module 301 is configured to receive a charge/discharge mode acquisition instruction for the intelligent battery if the current condition meets a preset control trigger condition.

The determining module 302 is configured to determine, according to the charge/discharge mode obtaining instruction, a current battery mode of the intelligent battery, where the current battery mode includes a battery charging mode or a battery discharging mode.

And a control module 303, configured to perform a device control operation matched with the current battery mode according to the current battery mode.

Therefore, compared with the existing device control method, the device intelligent control device based on the BMS described in the embodiment 3 is beneficial to improving tracking instantaneity and rationality of the battery mode of the intelligent battery, further improving determination convenience and determination efficiency of the battery mode of the intelligent battery, further improving accuracy and reliability of the determined battery mode of the intelligent battery, further improving execution timeliness and execution reliability of device control operation, further improving control efficiency, control convenience and control accuracy of the device, and further improving energy use controllability and accuracy of the intelligent battery.

In an alternative embodiment, as shown in fig. 4, the apparatus may further include:

the initialization module 304 is configured to perform a matched power-on initialization operation according to the intelligent battery and the intelligent terminal before the instruction receiving module 301 receives the charge-discharge mode acquisition instruction for the intelligent battery.

Therefore, compared with the existing device control method, the device described in fig. 4 can provide the power-on initialization function, which is beneficial to improving the integrity of the device control method, avoiding the influence of the historical device control operation on the current device control operation to a certain extent, and improving the pertinence and accuracy of the current device control operation.

In another alternative embodiment, the initialization module 304 specifically includes:

determining a first application state parameter with a first association relation with the intelligent terminal, and executing a matched first initialization operation on the first application state parameter according to the application information of the first application state parameter;

determining a second application state parameter with a second association relation with the intelligent battery, and executing a matched second initialization operation on the second application state parameter according to the application information of the second application state parameter;

And determining a third application state parameter with a third association relation with the intelligent terminal and the intelligent battery, and executing a matched third initialization operation on the third application state parameter according to the application information of the third application state parameter.

It can be seen that, implementing the apparatus described in fig. 4 may further perform the matched initialization operation on the first application state parameter corresponding to the intelligent terminal, the second application state parameter corresponding to the intelligent battery, and the third application state parameter corresponding to the intelligent terminal and the intelligent battery, respectively, which is advantageous to improve the comprehensiveness and rationality of the initialization method, and further, to improve the comprehensiveness and accuracy of the initialization execution objects (i.e., the first application state parameter, the second application state parameter, and the third application state parameter), and to improve the pertinence, flexibility, and execution effectiveness of different initialization operations, thereby being advantageous to improve the accuracy and reliability of the determined initialization result.

In yet another alternative embodiment, as shown in fig. 4, the apparatus may further include:

a first judging module 305, configured to judge, according to the determined operation data, whether the current situation meets a preset control trigger condition before the instruction receiving module 301 receives the instruction for acquiring the charge and discharge mode of the intelligent battery; when the determination result is yes, the instruction receiving module 301 performs the above-described operation of receiving the charge-discharge mode acquisition instruction for the smart battery.

The instruction generating module 306 is configured to generate an interlock safety processing instruction when the first judging module 305 judges that the current condition does not satisfy the control trigger condition.

The control module 303 is further configured to perform a matched security processing operation on the intelligent battery and the intelligent terminal according to the interlocking security processing instruction.

Wherein the operation data comprises battery operation data and/or user operation interaction data.

Therefore, the device described in fig. 4 can also provide corresponding coping methods for different control trigger conditions, and when the control trigger conditions are not met, an interlocking safety processing instruction is generated and corresponding safety processing operation is executed, so that compared with the existing equipment control method, the comprehensiveness and rationality of the equipment control method are improved, the control pertinence, flexibility, accuracy and reliability of the equipment are improved, the safety processing timeliness and accuracy of the intelligent battery and the intelligent terminal are improved, the service lives of the intelligent battery and the intelligent terminal are prolonged to a certain extent, and the equipment control operation inefficiency caused by equipment abnormality is effectively prevented.

In yet another alternative embodiment, the first determining module 305 determines, according to the determined operation data, whether the current situation meets the preset control trigger condition specifically includes:

When the determined operation data comprise battery operation data, judging whether the intelligent battery is in an abnormal state according to the battery operation data; when judging that the intelligent battery is in an abnormal state, determining that the current condition does not meet a preset control triggering condition; when judging that the intelligent battery is not in an abnormal state, determining that the current condition meets a preset control triggering condition;

when the determined operation data comprise user operation interaction data, determining an operation instruction matched with the user operation interaction data according to the user operation interaction data; judging whether the operation instruction is in a preset unsafe instruction set or not; when the operation instruction is judged to be in the unsafe instruction set, determining that the current condition does not meet the preset control trigger condition; and when the operation instruction is judged not to be in the unsafe instruction set, determining that the current condition meets the preset control trigger condition.

Therefore, the device described in fig. 4 can also determine that the control trigger condition meets the condition by analyzing the battery running state or analyzing the user operation interaction instruction, which is beneficial to improving the diversity, flexibility and comprehensiveness of the method for determining the control trigger condition meets the condition, and further is beneficial to improving the accuracy and reliability of the determined control trigger condition meets the condition, thereby being beneficial to improving the timeliness and efficiency of the device control aiming at the control trigger condition meets the condition, and is beneficial to improving the intelligence and user experience of the device control method by combining the man-machine interaction function.

In yet another alternative embodiment, the manner in which the control module 303 performs the device control operation that matches the current battery mode according to the current battery mode specifically includes:

if the current battery mode comprises a battery charging mode, determining charging data of the intelligent battery, wherein the charging data comprise charging current data and charging voltage data;

according to the charging data, calculating a charging power result of the intelligent battery, and determining the charging power result as the content to be displayed of a display function module in the intelligent terminal;

controlling the display function module to execute corresponding display operation based on the content to be displayed;

and/or the number of the groups of groups,

and if the current battery mode comprises a battery charging mode, executing interrupt output operation on other functional modules in the intelligent terminal.

It can be seen that, implementing the apparatus described in fig. 4 can also provide corresponding and specific device control operations for the case that the current battery mode includes the battery charging mode, further, the device control operations include display operations of the display function module and/or interrupt output operations of other function modules, which is beneficial to improving pertinence and flexibility of the device control operations, further, is beneficial to improving execution rationality and execution accuracy of the device control operations, and further, is beneficial to real-time monitoring and displaying of charging conditions (such as charging power) of the intelligent battery, further, is beneficial to improving real-time monitoring, checking efficiency and convenience of the charging conditions of the intelligent battery, further, is beneficial to improving timeliness of coping with charging anomalies of the intelligent battery and safety reliability of charging use of the intelligent battery, and further, is also beneficial to improving control independence, pertinence and accuracy of different function modules included in the intelligent terminal.

In yet another alternative embodiment, the manner in which the control module 303 performs the device control operation that matches the current battery mode according to the current battery mode specifically includes:

if the current battery mode comprises a battery discharging mode, determining discharging data of the intelligent battery, wherein the discharging data comprise discharging current data and discharging voltage data;

according to the discharge data, calculating a discharge power result of the intelligent battery, and determining the discharge power result as the content to be displayed of a display function module in the intelligent terminal;

controlling the display function module to execute corresponding display operation based on the content to be displayed;

and/or the number of the groups of groups,

if the current battery mode comprises a battery discharging mode, judging whether at least one target functional module which needs to be powered by the intelligent battery except the display functional module exists in the intelligent terminal, and if so, determining all the target functional modules and determining discharging requirement parameters of each target functional module;

and controlling the intelligent battery to execute matched discharging operation on each target functional module based on the discharging demand parameters and the discharging data of each target functional module.

It can be seen that, implementing the apparatus described in fig. 4 can also provide corresponding and specific device control operations for the case that the current battery mode includes the battery discharge mode, further, the device control operations include display operations of the display function module and/or discharge operations of the intelligent battery, which is favorable to improving pertinence and flexibility of the device control operations, further, is favorable to improving execution rationality and execution accuracy of the device control operations, and further, is also favorable to real-time monitoring and displaying of discharge conditions (such as discharge power) of the intelligent battery, is also favorable to improving real-time monitoring, checking efficiency and convenience of the discharge conditions of the intelligent battery, further, is favorable to improving timeliness of handling of discharge abnormality of the intelligent battery and safety reliability of discharge use of the intelligent battery, and further, is also favorable to controlling discharge accuracy and discharge suitability of the intelligent battery to a target function module to be powered, further is favorable to energy saving and reducing loss of the intelligent battery, and further, is also favorable to improving control independence, pertinence and accuracy of different function modules included in the intelligent terminal.

In yet another alternative embodiment, the manner in which the control module 303 controls the display function module to perform the corresponding display operation based on the content to be displayed specifically includes:

monitoring operation instruction data aiming at the display function module, and determining a display mode corresponding to the display function module according to the operation instruction data, wherein the display mode comprises a dormant display mode or a conventional display mode;

when the display mode comprises a dormant display mode, controlling the display function module to execute corresponding dormant display operation based on the content to be displayed;

when the display mode includes a normal display mode, the display function module is controlled to execute a corresponding normal display operation based on the content to be displayed.

Therefore, compared with the existing equipment control method, the device described in the implementation of fig. 4 can also provide two display modes of a sleep display mode and a normal display mode and control the display function module to execute corresponding display operation based on the determined display mode, so that the diversity and flexibility of the display mode of the display function module are improved, the display intellectualization, the display pertinence and the display diversity of the display function module are improved, the execution pertinence of the execution control operation is improved, and the energy consumption of the display function module is reduced and the energy-saving display is realized to a certain extent.

In yet another alternative embodiment, the manner in which the control module 303 determines the display mode corresponding to the display function module according to the operation instruction data specifically includes:

determining a target operation instruction associated with the display function module according to the operation instruction data, and determining instruction type information corresponding to the target operation instruction;

determining instruction time information corresponding to a target operation instruction according to the operation instruction data;

judging whether the target operation instruction meets a preset wake-up control condition according to the instruction type information and the instruction time information;

when the target operation instruction is judged to meet the wake-up control condition, determining that the display mode corresponding to the display function module comprises a conventional display mode;

and when the target operation instruction is judged not to meet the wake-up control condition, determining that the display mode corresponding to the display function module comprises a dormant display mode.

It can be seen that the device described in fig. 4 can also determine instruction type information and instruction time information, and determine a specific display mode of the display function module according to the instruction type information and the instruction time information, so that, compared with the existing device control method, the rationality and the dependence of the display mode determining method of the display function module are improved, and further, the accuracy and the reliability of the determined display mode are improved.

In yet another alternative embodiment, as shown in fig. 4, the apparatus may further include:

the monitoring module 307 is configured to monitor real-time status data corresponding to the intelligent battery and the intelligent terminal after the control module 303 performs the device control operation matched with the current battery mode according to the current battery mode, and when it is determined that the intelligent terminal and the intelligent battery are in a normal running state.

The determining module 302 is further configured to determine an operation condition corresponding to the intelligent battery and the intelligent terminal according to the real-time condition data.

And a second judging module 308, configured to judge whether the intelligent battery meets a preset abnormal processing triggering condition according to the running condition.

The control module 303 is further configured to execute a suspend operation control operation on the intelligent terminal when the second judging module 308 judges that the intelligent battery meets the abnormal processing triggering condition, and execute a matched abnormal processing operation on the intelligent battery according to the battery condition.

Therefore, when the device described in fig. 4 is implemented to further provide an abnormal processing triggering monitoring method of the intelligent battery and when it is determined that the intelligent battery meets the abnormal processing triggering condition, corresponding control operations are performed on the intelligent terminal and the intelligent battery, so that compared with the existing device control method, the device control method is beneficial to improving the operation monitoring instantaneity and the abnormal processing timeliness of the intelligent battery and the intelligent terminal, and further beneficial to improving the operation stability and the operation reliability of the intelligent battery and the intelligent terminal, and further beneficial to improving the accuracy, the safety and the reliability of device control.

In yet another alternative embodiment, the control module 303 is further configured to execute a corresponding resume operation control operation on the intelligent terminal and the intelligent battery when it is detected that the intelligent battery meets a preset exception handling completion condition.

It can be seen that the device described in fig. 4 can also execute the corresponding resume operation control operation when the intelligent battery meets the exception handling completion condition, which is advantageous to improve the integrity and rationality of the device control method and the exception handling method of the intelligent battery, and further to improve the exception handling reliability and rationality of the intelligent battery and the intelligent terminal, compared with the existing device control method.

In yet another alternative embodiment, the second determining module 308 determines, according to the operation condition, whether the intelligent battery meets the preset exception handling triggering condition, by specifically including:

when the running condition comprises the battery electric quantity condition of the intelligent battery, determining the current electric quantity value of the intelligent battery according to the battery circuit condition; judging whether the current electric quantity value is smaller than or equal to a preset abnormal electric quantity value threshold value or not; when the current electric quantity value is judged to be smaller than or equal to the abnormal electric quantity value threshold value, determining that the intelligent battery meets a preset abnormal processing condition;

When the running condition comprises the function execution condition of the intelligent terminal and the function execution condition is used for indicating that the intelligent terminal is in an interrupt execution state, analyzing the guidance of the intelligent battery and the intelligent terminal in the interrupt execution state according to the real-time condition data; judging whether the guidance quality is larger than or equal to a preset guidance quality threshold value; and when judging that the guidance quality is greater than or equal to the guidance quality threshold value, determining that the intelligent battery meets the preset abnormal processing condition.

It can be seen that, implementing the apparatus described in fig. 4 can also provide a corresponding method for determining whether the abnormal processing condition meets the condition according to the operating condition including the battery power condition of the intelligent battery or the operating condition including the function execution condition of the intelligent terminal, which is advantageous to improve the comprehensiveness, rationality and flexibility of the method for determining whether the abnormal processing condition meets the condition, and further to improve the accuracy and reliability of the determined abnormal processing condition meets the condition, thereby being advantageous to improve the abnormality discovery timeliness and the abnormality processing timeliness of the intelligent battery.

Example IV

Referring to fig. 5, fig. 5 is a schematic structural diagram of an intelligent control device for a BMS-based device according to an embodiment of the present invention. The apparatus described in fig. 5 may include a server, where the server includes a local server or a cloud server, and embodiments of the present invention are not limited. As shown in fig. 5, the apparatus may include:

A memory 401 storing executable program codes;

a processor 402 coupled with the memory 401;

further, an input interface 403 and an output interface 404 coupled to the processor 402 may be included;

the processor 402 invokes executable program codes stored in the memory 401, for performing the steps in the BMS-based device intelligent control method described in the first or second embodiment.

Example five

The embodiment of the invention discloses a computer storage medium storing a computer program for electronic data exchange, wherein the computer program causes a computer to execute the steps in the intelligent control method of the BMS-based device described in the first embodiment or the second embodiment.

Example six

An embodiment of the present invention discloses a computer program product comprising a non-transitory computer-readable storage medium storing a computer program, and the computer program is operable to cause a computer to perform the steps in the BMS-based device intelligent control method described in the first or second embodiment.

The apparatus embodiments described above are merely illustrative, wherein the modules illustrated as separate components may or may not be physically separate, and the components shown as modules may or may not be physical, i.e., may be located in one place, or may be distributed over a plurality of network modules. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of this embodiment. Those of ordinary skill in the art will understand and implement the present invention without undue burden.

From the above detailed description of the embodiments, it will be apparent to those skilled in the art that the embodiments may be implemented by means of software plus necessary general hardware platforms, or of course by means of hardware. Based on such understanding, the foregoing technical solutions may be embodied essentially or in part in the form of a software product that may be stored in a computer-readable storage medium including Read-Only Memory (ROM), random-access Memory (Random Access Memory, RAM), programmable Read-Only Memory (Programmable Read-Only Memory, PROM), erasable programmable Read-Only Memory (Erasable Programmable Read Only Memory, EPROM), one-time programmable Read-Only Memory (OTPROM), electrically erasable programmable Read-Only Memory (EEPROM), compact disc Read-Only Memory (Compact Disc Read-Only Memory, CD-ROM) or other optical disc Memory, magnetic disc Memory, tape Memory, or any other medium that can be used for computer-readable carrying or storing data.

Finally, it should be noted that: the embodiment of the invention discloses an intelligent control method and device for equipment based on BMS, which are disclosed by the embodiment of the invention only for illustrating the technical scheme of the invention, but not limiting the technical scheme; although the invention has been described in detail with reference to the foregoing embodiments, those of ordinary skill in the art will understand that; the technical scheme recorded in the various embodiments can be modified or part of technical features in the technical scheme can be replaced equivalently; such modifications and substitutions do not depart from the spirit and scope of the corresponding technical solutions.

Claims (8)

1. A method for intelligent control of a BMS-based device, the method comprising:

if the current condition meets a preset control trigger condition, receiving a charge and discharge mode acquisition instruction aiming at the intelligent battery;

determining a current battery mode of the intelligent battery according to the charge-discharge mode acquisition instruction, wherein the current battery mode comprises a battery charge mode or a battery discharge mode;

according to the current battery mode, executing equipment control operation matched with the current battery mode;

And performing a device control operation matched with the current battery mode according to the current battery mode, including:

if the current battery mode comprises the battery charging mode, determining charging data of the intelligent battery, wherein the charging data comprises charging current data and charging voltage data; according to the charging data, calculating a charging power result of the intelligent battery, and determining the charging power result as the content to be displayed of a display function module in the intelligent terminal; controlling the display function module to execute corresponding display operation based on the content to be displayed; executing interrupt output operation on other functional modules in the intelligent terminal;

if the current battery mode comprises the battery discharging mode, determining discharging data of the intelligent battery, wherein the discharging data comprise discharging current data and discharging voltage data; calculating a discharge power result of the intelligent battery according to the discharge data, and determining the discharge power result as the content to be displayed of a display function module in the intelligent terminal; controlling the display function module to execute corresponding display operation based on the content to be displayed; judging whether at least one target functional module needing power supply of the intelligent battery exists in the intelligent terminal except the display functional module, and determining all the target functional modules and determining discharge demand parameters of each target functional module when the judgment result is yes; and controlling the intelligent battery to execute matched discharging operation on each target functional module based on the discharging demand parameter of each target functional module and the discharging data.

2. The BMS-based device intelligent control method according to claim 1, wherein before the receiving a charge/discharge mode acquisition instruction for a smart battery, the method further comprises:

performing matched power-on initialization operation according to the intelligent battery and the intelligent terminal;

and performing a matched power-on initialization operation according to the intelligent battery and the intelligent terminal, including:

determining a first application state parameter with a first association relation with an intelligent terminal, and executing a matched first initialization operation on the first application state parameter according to application information of the first application state parameter;

determining a second application state parameter with a second association relation with the intelligent battery, and executing a matched second initialization operation on the second application state parameter according to the application information of the second application state parameter;

and determining a third application state parameter which has a third association relation with the intelligent terminal and the intelligent battery, and executing a matched third initialization operation on the third application state parameter according to the application information of the third application state parameter.

3. The BMS-based device intelligent control method according to claim 2, wherein before the receiving a charge-discharge mode acquisition instruction for a smart battery, the method further comprises:

Judging whether the current condition meets a preset control triggering condition according to the determined operation data;

when the judgment result is yes, executing the operation of receiving the charge and discharge mode acquisition instruction aiming at the intelligent battery;

when the judgment result is negative, generating an interlocking safety processing instruction, and executing matched safety processing operation on the intelligent battery and the intelligent terminal according to the interlocking safety processing instruction;

wherein the operation data comprises battery operation data and/or user operation interaction data;

and judging whether the current condition meets a preset control triggering condition according to the determined operation data, wherein the method comprises the following steps:

when the determined operation data comprise the battery operation data, judging whether the intelligent battery is in an abnormal state or not according to the battery operation data; when the intelligent battery is judged to be in the abnormal state, determining that the current condition does not meet a preset control triggering condition; when the intelligent battery is judged not to be in the abnormal state, determining that the current condition meets a preset control triggering condition;

when the determined operation data comprise the user operation interaction data, determining an operation instruction matched with the user operation interaction data according to the user operation interaction data; judging whether the operation instruction is in a preset unsafe instruction set or not; when the operation instruction is judged to be in the unsafe instruction set, determining that the current condition does not meet a preset control trigger condition; and when the operation instruction is judged not to be in the unsafe instruction set, determining that the current condition meets a preset control trigger condition.

4. The BMS-based device intelligent control method according to claim 1, wherein the controlling the display function module to perform the corresponding display operation based on the content to be displayed comprises:

monitoring operation instruction data aiming at the display function module, and determining a display mode corresponding to the display function module according to the operation instruction data, wherein the display mode comprises a dormant display mode or a normal display mode;

when the display mode comprises the dormant display mode, controlling the display function module to execute corresponding dormant display operation based on the content to be displayed;

when the display mode comprises the normal display mode, controlling the display function module to execute corresponding normal display operation based on the content to be displayed;

and determining a display mode corresponding to the display function module according to the operation instruction data, including:

determining a target operation instruction associated with the display function module according to the operation instruction data, and determining instruction type information corresponding to the target operation instruction;

determining instruction time information corresponding to the target operation instruction according to the operation instruction data;

Judging whether the target operation instruction meets a preset wake-up control condition according to the instruction type information and the instruction time information;

when the target operation instruction is judged to meet the wake-up control condition, determining that the display mode corresponding to the display function module comprises a conventional display mode;

and when the target operation instruction is judged not to meet the wake-up control condition, determining that the display mode corresponding to the display function module comprises a dormant display mode.

5. The BMS-based device intelligent control method according to any one of claims 1 to 3, wherein after the performing of a device control operation matched to the current battery mode according to the current battery mode, the method further comprises:

when the intelligent terminal and the intelligent battery are determined to be in a normal running state, monitoring real-time condition data corresponding to the intelligent battery and the intelligent terminal, and determining running conditions corresponding to the intelligent battery and the intelligent terminal according to the real-time condition data;

judging whether the intelligent battery meets a preset abnormal processing triggering condition according to the running condition;

Executing a pause operation control operation on the intelligent terminal when the intelligent battery is judged to meet the abnormal processing triggering condition, and executing a matched abnormal processing operation on the intelligent battery according to the battery condition;

and, the method further comprises:

when the intelligent battery is detected to meet the preset abnormal processing completion condition, corresponding operation recovery control operation is executed on the intelligent terminal and the intelligent battery;

and judging whether the intelligent battery meets a preset abnormal processing triggering condition according to the running condition, wherein the method comprises the following steps:

when the running condition comprises a battery electric quantity condition of the intelligent battery, determining a current electric quantity value of the intelligent battery according to the battery circuit condition; judging whether the current electric quantity value is smaller than or equal to a preset abnormal electric quantity value threshold value or not; when the current electric quantity value is judged to be smaller than or equal to the abnormal electric quantity value threshold value, determining that the intelligent battery meets a preset abnormal processing condition;

when the running condition comprises a function execution condition of the intelligent terminal and the function execution condition is used for indicating that the intelligent terminal is in an interrupt execution state, analyzing the guidance of the intelligent battery and the intelligent terminal in the interrupt execution state according to the real-time condition data; judging whether the guidance quality is larger than or equal to a preset guidance quality threshold value; and when judging that the guidance is larger than or equal to the guidance threshold, determining that the intelligent battery meets a preset abnormal processing condition.

6. An intelligent control device of a BMS-based apparatus, the device comprising:

the instruction receiving module is used for receiving a charge and discharge mode acquisition instruction aiming at the intelligent battery if the current condition meets a preset control trigger condition;

the determining module is used for determining a current battery mode of the intelligent battery according to the charge-discharge mode acquisition instruction, wherein the current battery mode comprises a battery charge mode or a battery discharge mode;

the control module is used for executing equipment control operation matched with the current battery mode according to the current battery mode;

and the control module performs the device control operation matched with the current battery mode according to the current battery mode, wherein the device control operation matched with the current battery mode specifically comprises the following steps:

if the current battery mode comprises the battery charging mode, determining charging data of the intelligent battery, wherein the charging data comprises charging current data and charging voltage data; according to the charging data, calculating a charging power result of the intelligent battery, and determining the charging power result as the content to be displayed of a display function module in the intelligent terminal; controlling the display function module to execute corresponding display operation based on the content to be displayed; executing interrupt output operation on other functional modules in the intelligent terminal;

If the current battery mode comprises the battery discharging mode, determining discharging data of the intelligent battery, wherein the discharging data comprise discharging current data and discharging voltage data; calculating a discharge power result of the intelligent battery according to the discharge data, and determining the discharge power result as the content to be displayed of a display function module in the intelligent terminal; controlling the display function module to execute corresponding display operation based on the content to be displayed; judging whether at least one target functional module needing power supply of the intelligent battery exists in the intelligent terminal except the display functional module, and determining all the target functional modules and determining discharge demand parameters of each target functional module when the judgment result is yes; and controlling the intelligent battery to execute matched discharging operation on each target functional module based on the discharging demand parameter of each target functional module and the discharging data.

7. An intelligent control device of a BMS-based apparatus, the device comprising:

a memory storing executable program code;

a processor coupled to the memory;

The processor invokes the executable program code stored in the memory to perform the BMS-based device intelligent control method of any of claims 1-5.

8. A computer storage medium storing computer instructions for performing the BMS-based appliance intelligent control method according to any one of claims 1-5 when called.