CN115484297B

CN115484297B - Interactive system and method based on energy storage equipment

Info

Publication number: CN115484297B
Application number: CN202210922747.7A
Authority: CN
Inventors: 张文锋
Original assignee: CSmartlink Information Technology Co Ltd
Current assignee: CSmartlink Information Technology Co Ltd
Priority date: 2022-08-02
Filing date: 2022-08-02
Publication date: 2023-09-08
Anticipated expiration: 2042-08-02
Also published as: CN115484297A

Abstract

The embodiment of the invention discloses an interaction system and method based on energy storage equipment, wherein the system comprises the following steps: the permission giving end is used for carrying out information input on the users based on various information input modes to obtain input information, and giving interaction permission to the corresponding users based on the input information; the user building end is used for taking the user endowed with the interaction authority as an interactable user and building a user priority tree based on the interaction priorities of all interactable users; the screening and sorting end is used for screening and sorting the simultaneous control instruction list based on the user priority tree to obtain an instruction execution list; the execution recording end is used for sequentially executing corresponding operations based on the instruction execution list, and simultaneously recording all control instructions and operation processes in real time to obtain an interaction control record file; the method is used for carrying out information input and authority giving on the interactive user, ensures the effectiveness and safety of the received instructions, and avoids execution conflict among the instructions by determining the priority of the user who sends the instructions.

Description

Interactive system and method based on energy storage equipment

Technical Field

The invention relates to the technical field of intelligent interaction, in particular to an interaction system and method based on energy storage equipment.

Background

Currently, energy storage is considered as a key technology for realizing low-carbon power systems. The outdoor power supply is a built-in lithium ion battery, can store electric energy and has an alternating-current output function. The product has light weight, high capacity, high power and convenient carrying, and can be used indoors or outdoors. Which may be selected for conventional charging or solar charging depending on the different use cases. The system can provide 100-240V AC output with super-high power, is provided with a plurality of direct current output modules such as 5V/9V/12V and the like, can not only start an automobile in an emergency, but also be suitable for emergency use of various loads, such as: and the consumer electronic products and the vehicle-mounted electrical appliances are powered, so that reliable power supply guarantee is provided.

However, the remote control mode of the interactive system of the current energy storage system is simpler, the received remote control instruction is directly executed, when the instruction content conflict or the instruction sending time is the same, the execution conflict between the instructions cannot be identified, the energy storage equipment is damaged or the state is frequently switched, the aging failure of the energy storage equipment is accelerated, and the validity and the safety of the received instruction cannot be ensured because the verification process of the user terminal sending the control instruction is not performed.

Therefore, the invention provides an interaction system and an interaction method based on energy storage equipment.

Disclosure of Invention

Based on this, there is a need to address the above-mentioned problems, and an interactive system and method based on an energy storage device are provided.

The invention provides an interaction system based on energy storage equipment, which comprises:

the permission giving end is used for carrying out information input on the users based on various information input modes to obtain input information, and giving interaction permission to the corresponding users based on the input information;

the user building end is used for taking the user endowed with the interaction authority as an interactable user and building a user priority tree based on the interaction priorities of all interactable users;

the screening and sorting end is used for screening and sorting the simultaneous control instruction list based on the user priority tree to obtain an instruction execution list;

and the execution recording end is used for controlling the energy storage equipment to sequentially execute corresponding operations based on the instruction execution list, and simultaneously recording all control instructions and operation processes in real time to obtain an interactive control record file.

Preferably, the authority verification terminal includes:

the input module is used for inputting information to the user based on the face input mode and the identity information input mode to obtain input information;

And the storage module is used for giving interactive authority to the user contained in the input information.

Preferably, the user builds the end, including:

the level determining module is used for regarding the user endowed with the interaction authority as an interactable user and determining the interaction priority of the interactable user;

the user setting-up module is used for setting up the user priority tree based on the layer height of each interactable user by taking the interactable priority of the interactable user as the layer height of the corresponding interactable user in the user priority tree.

Preferably, the level determining module includes:

the instruction sending unit is used for taking the user endowed with the interaction authority as an interactable user, sending priority determining instructions to all interactable users and receiving priority feedback instructions input by the interactable user;

the list generation unit is used for determining a priority feedback result corresponding to the interactable user based on the priority feedback instruction and generating a user priority ordering list corresponding to the interactable user based on the priority feedback result;

the difference judging unit is used for judging whether a difference ordering result exists in the user priority ordering list, if so, determining the priority to be determined corresponding to the difference ordering result and the corresponding user to be determined, and if not, determining the interactive priority of the interactable user based on the user priority ordering list;

The rule determining unit is used for acquiring an application scene of the energy storage device and determining a corresponding priority determining rule based on the application scene and the application scene-priority determining rule list;

the initial sequencing unit is used for calling out corresponding rule related information from the input information of the user to be determined based on the priority determining rule, and sequencing all the users to be determined according to the rule related information and the corresponding priority determining rule to obtain a first priority sequencing result;

the second sequencing unit is used for calculating the integrity value of the input information of the user to be determined, calculating the priority weight based on the integrity value, and determining a second priority sequencing result based on the priority weight and the first priority sequencing result;

the final sorting unit is used for determining the final priority of the user to be determined based on the priority to be determined and the second priority sorting result;

the final determining unit is used for determining the interaction priority of the interactable user based on the consistent sorting result in the user priority sorting list and the final priority of the user to be determined;

the method for calculating the integrity value of the input information of the user to be determined comprises the following steps:

Determining a first total byte number and a second total byte number of illegal bytes contained in each piece of sub-input information in the input information of the user to be determined and a third total byte number of which the attribute is inconsistent with the corresponding attribute of the sub-input information, and calculating the integrity value of the input information of the user to be determined based on the first total byte number, the second total byte number and the third total byte number:

wherein alpha is the integrity value of the input information of the user to be determined, i is the ith piece of input information of the user to be determined, n is the total number of pieces of input information contained in the input information of the user to be determined, y _i For a first total number of bytes, w, in the ith piece of sub-entry information of the user to be determined _i For a second total number of bytes, j, of offending bytes contained in the ith piece of sub-entry information of the user to be determined _i For a third total number of bytes, y, for which the attribute contained in the ith piece of sub-entry information of the user to be determined is inconsistent with the corresponding attribute of the sub-entry information _0i The method comprises the steps of inputting a standard total byte number corresponding to information for the ith sub-item of a user to be determined;

calculating a priority weight based on the integrity value, comprising:

wherein beta is ₀ For the currently calculated priority weight, alpha, of the input information of the user to be determined ₀ For the currently calculated integrity value of the input information of the user to be determined, m is the total number of all the users to be determined, j is the j-th user to be determined, alpha _j For the j-th user to be determined to enter informationIntegrity value.

Preferably, the screening and sorting end comprises:

the instruction receiving module is used for receiving control instructions of all interactable users in real time and recording the receiving time of the control instructions;

the simultaneous determination module is used for generating a simultaneous control instruction list based on the receiving time of each control instruction;

and the screening and sorting module is used for screening and sorting the simultaneous control instruction list based on the user priority tree to obtain an instruction execution list.

Preferably, the screening and sorting module comprises:

the judging unit is used for judging whether conflict control instruction groups with conflict relation exist in the simultaneous control instruction list or not;

the screening unit is used for determining the interaction priority of each conflict control instruction in the conflict control instruction group based on the user priority tree when conflict control instruction groups with conflict relation exist in the simultaneous control instruction list, deleting the conflict control instruction with lower interaction priority in the conflict control instruction group contained in the simultaneous control instruction list, and obtaining an executable instruction list;

The holding unit is used for regarding the simultaneous control instruction list as an executable instruction list if conflict control instruction groups which are in conflict relation with each other do not exist in the simultaneous control instruction list;

the ordering unit is used for ordering the executable instruction list based on the user priority tree to obtain an instruction priority list;

the mining unit is used for carrying out association limit mining on the instruction priority list to obtain association limit mining results, and carrying out instruction supplement on the instruction priority list based on the association limit mining results to obtain an instruction execution list.

Preferably, the excavating unit includes:

the instruction analysis subunit is used for carrying out instruction analysis on the first instruction contained in the instruction priority list to obtain the instruction content and the instruction attribute of the first instruction;

the vector determination subunit is used for identifying a limiting keyword in the instruction content, determining a first limiting object based on the limiting keyword, and determining a limiting pointing vector in the instruction priority list based on a first instruction to which the limiting keyword belongs and a second instruction corresponding to the first limiting object;

a vector screening subunit, configured to screen, based on the pointing direction of the limiting pointing vector, valid limiting pointing vectors from all instruction limiting pointing vectors included in the instruction priority list;

The first determining subunit is configured to determine, based on the attribute association rule list and the instruction attribute of each first instruction, an attribute association relationship between the first instructions included in the instruction priority list, and determine, based on the attribute restriction rule list and the instruction attribute of each first instruction, an attribute restriction relationship between the first instructions included in the instruction priority list;

the second determining subunit is used for determining a first limiting rule based on the limiting keywords corresponding to the effective limiting pointing vector and determining a content limiting relationship based on the first limiting rule and the first limiting object;

the first supplementing subunit is used for determining a first supplementing instruction based on a first limiting rule contained in the content limiting relation, determining a first inserting position of the first supplementing instruction in the instruction priority list based on the interactive priority of the interactable user corresponding to the first instruction corresponding to the first limiting object and the first supplementing instruction, and carrying out instruction supplementation on the instruction priority list based on the first supplementing instruction and the corresponding first inserting position to obtain a first supplementing list;

the second supplementing subunit is used for determining a second supplementing instruction based on an attribute limiting rule corresponding to the attribute limiting relation, determining a second inserting position of the second supplementing instruction in the first supplementing list based on a lower interaction priority and the second supplementing instruction contained in the attribute limiting relation, and carrying out instruction supplementation on the first supplementing list based on the second supplementing instruction and the corresponding second inserting position to obtain a second supplementing list;

The third supplementing subunit is configured to determine a third supplementing instruction based on an attribute association rule corresponding to the attribute association relationship, determine a third insertion position of the third supplementing instruction in the second supplementing list based on the interaction priority and the third supplementing instruction included in the attribute association relationship, and perform instruction supplementation on the second supplementing list based on the third supplementing instruction and the corresponding third insertion position to obtain an instruction execution list.

Preferably, the execution record end includes:

the instruction recording module is used for recording all control instructions and corresponding receiving time in real time and generating a corresponding receiving instruction recording file;

the execution recording module is used for controlling the energy storage equipment to sequentially execute corresponding operations based on the instruction execution list, recording the corresponding operation process and operation result and obtaining an execution recording file;

and the file summarizing module is used for summarizing the received instruction record file and the execution record file to obtain the interaction control record file.

Preferably, the execution record end further includes:

the record analysis module is used for analyzing the execution record file and identifying a fault operation result in the historical operation result;

the mode determining module is used for determining a corresponding automatic maintenance mode based on the fault operation result and the automatic maintenance mode table;

And the automatic maintenance module is used for executing corresponding automatic maintenance operation based on an automatic maintenance mode to obtain a maintenance result.

The application provides an interaction method based on energy storage equipment, which comprises the following steps:

s1: information input is carried out on the users based on various information input modes, input information is obtained, and interaction rights are given to the corresponding users based on the input information;

s2: the user endowed with the interaction authority is regarded as an interactable user, and a user priority tree is built based on the interaction priorities of all interactable users;

s3: screening and sorting the simultaneous control instruction list based on the user priority tree to obtain an instruction execution list;

s4: and controlling the energy storage equipment to sequentially execute corresponding operations based on the instruction execution list, and simultaneously recording all control instructions and operation processes in real time to obtain an interactive control record file.

Compared with the prior art, the application has the following beneficial effects:

the interactive user is subjected to information input and permission assignment, so that screening of instruction-issuing users is achieved, effectiveness and safety of received instructions are guaranteed, screening and sorting of simultaneous control instructions are achieved through priority determination of the instruction-issuing users, potential hidden hazards among the instructions are eliminated, execution conflicts among the instructions are avoided, damage to energy storage equipment or frequent state switching are avoided, and aging faults of the energy storage equipment are relieved.

Drawings

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

Wherein:

FIG. 1 is a schematic diagram of an interactive system based on an energy storage device according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a right verification end in an embodiment of the present invention;

FIG. 3 is a schematic diagram of a user end in an embodiment of the present invention;

FIG. 4 is a schematic diagram of a level determining module according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a screening and sorting end according to an embodiment of the present invention;

FIG. 6 is a schematic diagram of a screening and sorting module according to an embodiment of the present invention;

FIG. 7 is a schematic diagram of an excavating unit according to an embodiment of the present invention;

FIG. 8 is a schematic diagram of an execution record end according to an embodiment of the present invention;

FIG. 9 is a schematic diagram of a recording end of another embodiment of the present invention;

fig. 10 is a flowchart of an interaction method based on energy storage devices in an embodiment of the present invention.

FIG. 11 is an application environment diagram of an energy storage device-based interaction method in one embodiment;

FIG. 12 is a block diagram of a computer device in one embodiment.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but 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 invention provides an interactive system based on energy storage equipment, referring to fig. 1, comprising:

In this embodiment, the information entry means is, for example: a face entry mode and an identity information entry mode.

In this embodiment, the input information is information of the corresponding user obtained after the user is input with information based on a plurality of information input modes.

In this embodiment, the interaction right is a right that allows the corresponding user to interact with the energy storage device.

In this embodiment, the interactable user is the user to which the interaction right is assigned.

In this embodiment, the user priority tree is a tree structure of the priority ordering result of the interactable users from high to low in the table needle priority built based on the interaction priority of the interactable users.

In this embodiment, the instruction execution list is a list including instructions obtained by filtering and sorting the simultaneous control instruction list based on the user priority tree.

In this embodiment, the corresponding operations are for example: user authentication operation, charging operation, discharging operation, low battery mode adjustment operation.

In this embodiment, the control instruction is an instruction for controlling the energy storage device to perform a corresponding operation, which is received in real time and can be input by an interactive user.

In this embodiment, the operation process is a process of controlling the energy storage device to sequentially execute corresponding operations based on the instruction execution list.

In this embodiment, the interactive control record file is a record file obtained after recording all control instructions and operation processes in real time.

The beneficial effects of the technology are as follows: the interactive user is subjected to information input and permission assignment, so that screening of instruction-issuing users is achieved, effectiveness and safety of received instructions are guaranteed, screening and sorting of simultaneous control instructions are achieved through priority determination of the instruction-issuing users, potential hidden hazards among the instructions are eliminated, execution conflicts among the instructions are avoided, damage to energy storage equipment or frequent state switching are avoided, and aging faults of the energy storage equipment are relieved.

In one embodiment, the rights verification end, referring to fig. 2, comprises:

In this embodiment, the face entry mode is a mode in which information is entered for the user by entering a face image of the user.

In this embodiment, the identity information input mode is a mode of inputting information to the user by inputting the identity information of the user.

The beneficial effects of the technology are as follows: the user is subjected to information input based on a face input mode or an identity information input mode, so that sufficient user information can be obtained, and the identity verification mode of the user is enriched.

In one embodiment, the user-set-up end, referring to fig. 3, comprises:

In this embodiment, the interaction priority is a control priority corresponding to the control of the energy storage device by the corresponding interactable user, for example: and if the priority of the user A is higher than that of the user B, when the user A and the user B input control instructions at the same time, the control instructions input by the user A are executed first, or when control conflicts exist in the control instructions input by the user A and the user B at the same time (for example, the user A controls the energy storage device to be in a low-power mode and the user B controls the energy storage device to be in a low-power mode), the control instructions input by the user A are selected to be executed.

In this embodiment, a user priority tree is built based on the layer height of each interactable user, namely:

setting the corresponding interactable users in the corresponding layers in the user priority tree based on the layer heights of the interactable users, and obtaining the user priority tree until all interactable users are set.

The beneficial effects of the technology are as follows: and building a user priority tree based on the interaction priorities of the users, so that the priorities of all interactable users are more visual, and the simultaneous control instructions are screened and sequenced for the follow-up to obtain a reference basis.

In one embodiment, the level determination module, referring to FIG. 4, comprises:

calculating a priority weight based on the integrity value, comprising:

wherein beta is ₀ For the currently calculated priority weight, alpha, of the input information of the user to be determined ₀ For the currently calculated integrity value, m, of the input information of the user to be determinedFor the total number of all users to be determined, j is the j-th user to be determined, alpha _j And the integrity value of the input information of the jth user to be determined.

In this embodiment, the priority determining instruction is an instruction for requesting to determine the interaction priority of the interactable user from the interactable user.

In this embodiment, the priority feedback instruction is an instruction input by the interactable user and used for feeding back a result of determining the priority of the interactable user.

In this embodiment, the priority feedback result is a priority determination result of each interactive user input by the interactive user determined based on the priority feedback instruction.

In this embodiment, the user prioritized list is a list of user prioritized results corresponding to interactable users generated based on the priority feedback results.

In this embodiment, the difference ranking result is a non-uniform ranking result in the user ranking list of all interactable users.

In this embodiment, the priority to be determined is the priority in the difference sequencing result.

In this embodiment, the user to be determined is the interactable user in the difference ordering result.

In this embodiment, the application scenario is, for example: the method is applied to daily use in families or industrial production in enterprises.

In this embodiment, the application scenario-priority determining rule list is a list including priority determining rules corresponding to the application scenario.

In this embodiment, the priority determination rule is based on a rule determined based on the application scenario and the priority determined by the application scenario-priority determination rule list, for example: when the application scene is used for industrial production in enterprises, the rules of priority determination are determined according to the positions of interactable users of the production departments from high to low.

In this embodiment, the rule-related information is information related to a priority determination rule in the input information.

In this embodiment, the first prioritized results are results obtained after prioritizing all the users to be determined based on the rule related information and the corresponding priority determining rule.

In this embodiment, the integrity value is a numerical value representing the information integrity of the input information of the user.

In this embodiment, the priority weight is a weight value related to the integrity value for determining the interaction priority of the user.

In this embodiment, the second prioritized results are determined based on the priority weights and the first prioritized results.

In this embodiment, the final priority is the interaction priority of the user to be determined, which is finally determined based on the priority to be determined and the second priority ranking result.

In this embodiment, based on the consistent ranking result in the user priority ranking list and the final priority of the user to be determined, the interactive priority of the interactable user is determined to be

And summarizing the consistent sorting result in the user priority sorting list and the final priority of the user to be determined to obtain the interaction priority of each interactable user.

In this embodiment, the sub-input information is a single piece of input information contained in the input information, for example, the sex is female, and the first name is Zhang three.

In this embodiment, the first total number of bytes is the total number of bytes contained in the sub-entry information.

In this embodiment, the second total number of bytes is the total number of bytes of the offending bytes contained in the sub-entry information.

In this embodiment, the violation bytes are bytes that violate the entry rules, such as various literal symbols … …, @, etc.

In this embodiment, the third total byte number is the total byte number contained in the sub-entry information and inconsistent with the corresponding attribute of the sub-entry information.

In this embodiment, bytes that are inconsistent with the corresponding attributes of the sub-entry information, such as: the sub-entry information is twenty-five years old and the standard format should be 25 years old, then the byte that is inconsistent with the corresponding attribute of the sub-entry information is "twenty-five".

In this embodiment, the standard total byte number is the total number of bytes corresponding to the standard format of the sub-input information, for example: the standard format is "age 25 years", then the standard total number of bytes is 5.

The beneficial effects of the technology are as follows: the method comprises the steps of firstly determining the priority of the interactable user based on the priority determination result fed back by the interactable user, secondly determining the user to be determined in the difference sequencing result in the priority feedback result based on the priority determination rule determined by the application scene, thirdly determining the user to be determined in the difference sequencing result in combination with the information integrity, further accurately determining the interaction priority of the interactable user, determining the interaction priority by taking the user feedback, the application scene and the input information integrity into consideration, and improving the accuracy of the interaction priority.

In one embodiment, the screening ranking side, referring to fig. 5, includes:

In this embodiment, the receiving time is the time when the interaction system based on the energy storage device receives the corresponding control instruction.

In this embodiment, the simultaneous control instruction list is a list obtained by summarizing control instructions with the same receiving time.

The beneficial effects of the technology are as follows: the simultaneous control instructions Lei Biao are determined based on the receiving time, and the simultaneous control instruction list is screened and sequenced based on the user priority tree to obtain the instruction execution list, so that the screening and sequencing of the simultaneous control instructions are realized, potential hidden danger among the instructions is eliminated, execution conflict among the instructions is avoided, damage to the energy storage equipment or frequent state switching is avoided, and ageing faults of the energy storage equipment are slowed down.

In one embodiment, the filter ordering module, referring to FIG. 6, comprises:

In this embodiment, the conflict control instruction set is an instruction set composed of control instructions having a conflict relationship with each other.

In this embodiment, it is determined whether there is a conflict control instruction set having a conflict relationship with each other in the simultaneous control instruction list, that is: based on the conflict relation instruction list (i.e. a list containing all instructions with conflict relation), judging whether conflict control instruction groups with conflict relation exist in the simultaneous control instruction list.

In this embodiment, the conflict control instruction is a control instruction included in the conflict control instruction set.

In this embodiment, the executable instruction list is an instruction list obtained after deleting the conflict control instruction with a lower interaction priority in the conflict control instruction group included in the simultaneous control instruction list.

In this embodiment, the instruction priority list is an instruction list obtained after the executable instruction list is ordered based on the interaction priority tree.

In this embodiment, the association constraint mining result is a result obtained after association constraint mining is performed on the instruction priority list.

The beneficial effects of the technology are as follows: the control instructions which are in conflict relation with each other and contained in the simultaneous control instruction list are identified, the interaction priority of the user is sent out by combining the control instructions, the simultaneous control instructions Lei Biao are screened and sequenced, the result after screening and sequencing is subjected to association limiting mining, instruction supplementation is carried out based on association limiting mining, the problems of instruction execution conflict, execution sequence and instruction association limiting which possibly occur in the control process of the energy storage equipment are solved, potential hidden dangers among the instructions are eliminated, execution conflict among the instructions is avoided, the situation that the energy storage equipment is damaged or the state is frequently switched is avoided, and the ageing fault of the energy storage equipment is relieved.

In one embodiment, the excavation unit, referring to fig. 7, includes:

In this embodiment, the first instruction is an instruction included in the instruction priority list.

In this embodiment, the instruction content is the content in the first instruction read after the first instruction is parsed, for example: the low battery mode is turned off.

In this embodiment, the instruction attribute is an attribute in the first instruction read after the first instruction is parsed, for example: parameter setting instructions and state control instructions.

In this embodiment, the limiting keywords are keywords that are included in the instruction content and limit the control process of other interactable users, for example: and modifying the charging verification mode of the user A into face verification, and limiting keywords into 'user A' and 'modification' and 'charging verification mode'.

In this embodiment, the identifying of the limiting keywords in the instruction content is: is a restriction keyword included in a restriction keyword list (i.e., a list including restriction keywords) included in the instructed contents.

In this embodiment, the first constraint object is a constraint object included in the constraint keyword, for example: and modifying the charging verification mode of the user A into face verification, and limiting the object to be the user A.

In this embodiment, the second instruction is a control instruction issued by the second restriction object in the instruction priority list.

In this embodiment, the restriction pointing vector is a vector in which the first instruction points to the row in which the second instruction points.

In this embodiment, the valid restriction vector is a valid restriction vector selected from all instruction restriction vectors included in the instruction priority list based on the direction of the restriction vector.

In this embodiment, based on the pointing direction of the limiting pointing vector, the valid limiting pointing vector is selected from all the limiting pointing vectors of the instructions included in the instruction priority list, which is: and taking the limiting pointing vector with the interaction priority of the interactable user belonging to the instruction of the end point position corresponding to the limiting pointing vector lower than that of the interactable user belonging to the instruction of the start point position corresponding to the limiting pointing vector as an effective limiting pointing vector.

In this embodiment, the attribute association rule list is a list including attribute association rules between control instructions.

In this embodiment, the instruction attribute is an instruction attribute of the first instruction, for example: parameter control instructions and state control instructions.

In this embodiment, the attribute association relationship is a relationship between the first instructions associated with the existence attribute contained in the instruction priority list based on the attribute association rule list and the instruction attribute of each first instruction.

In this embodiment, the attribute limitation rule list is a list including attribute limitation rules between control instructions.

In this embodiment, the attribute restriction relationship is a relationship between first instructions having attribute restrictions contained in the instruction priority list determined based on the attribute restriction rule list and the instruction attribute of each first instruction.

In this embodiment, the first constraint rule is a constraint rule determined based on a constraint keyword corresponding to an effective constraint vector, for example: and modifying the charging verification mode of the user A into face verification, wherein the limiting keywords are 'user A' and 'modification' and 'charging verification mode', and the limiting rule is 'modification charging verification mode'.

In this embodiment, the content restriction relationship is a restriction rule determined based on the first restriction rule and the first restriction object, for example, the restriction rule is "modify charging verification mode" is "a user", and the content restriction relationship is: and modifying the charging verification mode of the user A.

In this embodiment, the first supplement instruction is an instruction for performing first supplement to the instruction priority list, which is determined based on a first constraint rule included in the content constraint relation.

In this embodiment, the first insertion position is an insertion position of the first supplementary instruction determined in the instruction priority list based on the interactive priority of the interactable user corresponding to the first instruction corresponding to the first restriction object and the first supplementary instruction, for example: the interactive priority of the interactable user corresponding to the first instruction corresponding to the first limiting object is 5 th level, the first supplementary instruction is 'modifying the charging verification mode of the user A', and then the control instruction of 'modifying the charging verification mode of the user A' is inserted into the middle of the control instruction with the interactive priority of 5 th level and the control instruction with the interactive priority of 4 th level.

In this embodiment, the first supplementary list is an instruction execution list obtained after instruction supplementation to the instruction priority list based on the first supplementary instruction and the corresponding first insertion position.

In this embodiment, the second supplementary instruction is a supplementary instruction determined based on an attribute limitation rule corresponding to the attribute limitation relationship, for example: the attribute limitation relation is: if the energy storage device cannot discharge more than five charging devices in the low-power mode, an attribute limitation relationship exists between an instruction A for starting the low-power mode of the energy storage device and an instruction B for discharging the fifth charging device, and before a control instruction for discharging the fifth charging device is executed, a second supplement instruction is a prompt for sending a charging operation to stop the existing 4 charging devices to the interactable user.

In this embodiment, the second insertion position is the insertion position of the second supplementary instruction determined in the first supplementary list based on the lower interaction priority and the second supplementary instruction included in the attribute-restricted relation.

In this embodiment, the second supplementary list is an instruction execution list obtained after instruction supplementation of the first supplementary list based on the second supplementary instruction and the corresponding second insertion position.

In this embodiment, the third supplementary instruction is a supplementary instruction determined by an attribute association rule corresponding to an attribute association relationship, for example: the attribute association relationship is: when the maximum discharge current of the energy storage device to the charging device in the low-power mode is 5A, an attribute limiting relation exists between an instruction A for starting the low-power mode of the energy storage device and an instruction B for discharging the charging device with the maximum discharge current, and before a control instruction of discharging the charging device with the maximum discharge current is executed, a third supplementary instruction is set to be 5A.

In this embodiment, the third insertion position is the insertion position of the third supplementary instruction determined in the second supplementary list based on the interaction priority and the third supplementary instruction included in the attribute association relationship.

In this embodiment, the instruction execution list is an instruction list obtained after instruction supplementation of the second supplementation list based on the third supplementation instruction and the corresponding third insertion position.

The beneficial effects of the technology are as follows: based on the content restriction relation and the association attribute and restriction attribute determined based on the instruction attribute, the association restriction rule among all the first instructions is mined, so that the arrangement of simultaneous control instructions is realized, instruction supplementation is performed based on association restriction mining, the problems of instruction execution conflict, execution sequence and instruction association restriction which may occur in the control process of the energy storage device are solved, potential hidden hazards among the instructions are eliminated, the execution conflict among the instructions is avoided, the damage of the energy storage device or the condition of frequent switching of states is avoided, and the aging fault of the energy storage device is slowed down.

In one embodiment, the execution record side, referring to fig. 8, includes:

In this embodiment, the receiving instruction record file is a record file generated by recording all control instructions and corresponding receiving times in real time.

In this embodiment, the execution record file is a record file obtained by recording the corresponding operation process and the operation result sequentially executed by the energy storage device based on the instruction execution list.

The beneficial effects of the technology are as follows: the whole interactive process of the energy storage device is recorded by controlling the process and the result recording of the corresponding operation of the energy storage device based on the instruction execution list and the control instruction and the corresponding receiving time.

In one embodiment, the execution record end, referring to fig. 9, further includes:

In this embodiment, the failure operation result is a failure result in the history operation result identified after the analysis of the execution record file.

In this embodiment, the history operation result is a result obtained after executing the control instruction by the energy storage device recorded in the execution record file.

In this embodiment, the automatic maintenance mode table is a list including automatic maintenance modes corresponding to each failure operation result.

In this embodiment, the automatic maintenance mode is a mode of automatically maintaining the fault operation result by the determined energy storage device based on the fault operation result and the automatic maintenance mode table.

In this embodiment, the maintenance result is a result obtained after the corresponding automatic maintenance operation is performed based on the automatic maintenance mode.

In this embodiment, the execution record file is analyzed, and a failure operation result in the historical operation results is identified, that is, the operation result of each control instruction in the execution record file is compared with the corresponding standard operation result, and an operation result inconsistent with the corresponding standard operation result is determined as the failure operation result.

The beneficial effects of the technology are as follows: the automatic maintenance mode is determined based on the identified fault operation result by analyzing and identifying the execution record file, and the energy storage equipment is maintained based on the automatic maintenance mode, so that the automatic monitoring and automatic maintenance of the energy storage equipment are realized.

FIG. 11 is an application environment diagram of an interaction method based on an energy storage device in one embodiment. Referring to fig. 11, the energy storage device-based interaction method is applied to an energy storage device-based interaction system. The energy storage device based interaction system includes a terminal 110 and a server 120. The terminal 110 and the server 120 are connected through a network, and the terminal 110 may be a desktop terminal or a mobile terminal, and the mobile terminal may be at least one of a mobile phone, a tablet computer, a notebook computer, and the like. The server 120 may be implemented as a stand-alone server or as a server cluster composed of a plurality of servers.

As shown in fig. 10, in one embodiment, an energy storage device-based interaction method is provided. The method can be applied to a terminal or a server, and the embodiment is applied to terminal illustration. The interaction method based on the energy storage device specifically comprises the following steps:

FIG. 12 illustrates an internal block diagram of a computer device in one embodiment. The computer device may specifically be a terminal or a server. As shown in fig. 12, the computer device includes a processor, a memory, and a network interface connected by a system bus. The memory includes a nonvolatile storage medium and an internal memory. The non-volatile storage medium of the computer device stores an operating system, and may also store a computer program that, when executed by the processor, causes the processor to implement an interaction method for the energy storage device. The internal memory may also have stored therein a computer program which, when executed by the processor, causes the processor to perform the method of interaction of the energy storage device. It will be appreciated by those skilled in the art that the structure shown in FIG. 12 is merely a block diagram of some of the structures associated with the present inventive arrangements and is not limiting of the computer device to which the present inventive arrangements may be applied, and that a particular computer device may include more or fewer components than shown, or may combine some of the components, or have a different arrangement of components.

In one embodiment, a computer device is presented comprising a memory and a processor, the memory storing a computer program that, when executed by the processor, causes the processor to perform the steps of:

In one embodiment, a computer-readable storage medium is provided, storing a computer program which, when executed by a processor, causes the processor to perform the steps of:

Those skilled in the art will appreciate that all or part of the processes in the methods of the above embodiments may be implemented by a computer program for instructing relevant hardware, where the program may be stored in a non-volatile computer readable storage medium, and where the program, when executed, may include processes in the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in embodiments provided herein may include non-volatile and/or volatile memory. The nonvolatile memory can include Read Only Memory (ROM), programmable ROM (PROM), electrically Programmable ROM (EPROM), electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double Data Rate SDRAM (DDRSDRAM), enhanced SDRAM (ESDRAM), synchronous Link DRAM (SLDRAM), memory bus direct RAM (RDRAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM), among others.

The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The foregoing examples illustrate only a few embodiments of the application and are described in detail herein without thereby limiting the scope of the application. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the application, which are all within the scope of the application. Accordingly, the scope of protection of the present application is to be determined by the appended claims. Please input the implementation content section.

Claims

1. An energy storage device-based interaction system, comprising:

The user building end comprises:

the level determining module is used for regarding the user endowed with the interaction authority as an interactable user and determining the interaction priority of the interactable user, and comprises the following steps: the instruction sending unit is used for taking the user endowed with the interaction authority as an interactable user, sending priority determining instructions to all interactable users and receiving priority feedback instructions input by the interactable user; the list generation unit is used for determining a priority feedback result corresponding to the interactable user based on the priority feedback instruction and generating a user priority ordering list corresponding to the interactable user based on the priority feedback result; the difference judging unit is used for judging whether a difference ordering result exists in the user priority ordering list, if so, determining the priority to be determined corresponding to the difference ordering result and the corresponding user to be determined, and if not, determining the interactive priority of the interactable user based on the user priority ordering list; the rule determining unit is used for acquiring an application scene of the energy storage device and determining a corresponding priority determining rule based on the application scene and the application scene-priority determining rule list; the initial sequencing unit is used for calling out corresponding rule related information from the input information of the user to be determined based on the priority determining rule, and sequencing all the users to be determined according to the rule related information and the corresponding priority determining rule to obtain a first priority sequencing result; the second sequencing unit is used for calculating the integrity value of the input information of the user to be determined, calculating the priority weight based on the integrity value, and determining a second priority sequencing result based on the priority weight and the first priority sequencing result; the final sorting unit is used for determining the final priority of the user to be determined based on the priority to be determined and the second priority sorting result; the final determining unit is used for determining the interaction priority of the interactable user based on the consistent sorting result in the user priority sorting list and the final priority of the user to be determined;

calculating a priority weight based on the integrity value, comprising:

Wherein beta is ₀ For the currently calculated priority weight, alpha, of the input information of the user to be determined ₀ For the currently calculated integrity value of the input information of the user to be determined, m is the total number of all the users to be determined, j is the j-th user to be determined, alpha _j The integrity value of the input information of the jth user to be determined is set;

the user setting-up module is used for setting up a user priority tree based on the layer height of each interactable user by taking the interactable priority of the interactable user as the layer height of the corresponding interactable user in the user priority tree;

2. The energy storage device-based interaction system of claim 1, wherein the rights verification side comprises:

3. The energy storage device-based interaction system of claim 1, wherein the screening ranking side comprises:

4. The energy storage device-based interaction system of claim 3, wherein the screening ranking module comprises:

5. The energy storage device-based interaction system of claim 4, wherein the mining unit comprises:

6. The energy storage device-based interaction system of claim 1, wherein the execution record side comprises:

7. The energy storage device-based interaction system of claim 6, wherein the execution record side further comprises:

8. An energy storage device-based interaction method, comprising:

s2: taking the user endowed with the interaction authority as an interactable user, building a user priority tree based on the interaction priorities of all interactable users, wherein the method comprises the following steps: the user endowed with the interaction authority is regarded as an interactable user, the interaction priority of the interactable user is determined, the interactable priority of the interactable user is regarded as the layer height of the corresponding interactable user in the user priority tree, and the user priority tree is built based on the layer height of each interactable user;

The user to be endowed with the interaction authority is regarded as an interactable user, and the determining the interaction priority of the interactable user comprises the following steps: the user endowed with the interaction authority is regarded as an interactable user, a priority determining instruction is sent to all interactable users, and a priority feedback instruction input by the interactable user is received; determining a priority feedback result corresponding to the interactable user based on the priority feedback instruction, and generating a user priority ordering list corresponding to the interactable user based on the priority feedback result; judging whether a difference ordering result exists in the user priority ordering list, if so, determining the priority to be determined corresponding to the difference ordering result and the corresponding user to be determined, otherwise, determining the interactive priority of the interactable user based on the user priority ordering list; acquiring an application scene of the energy storage equipment, and determining a corresponding priority determination rule based on the application scene and an application scene-priority determination rule list; calling out corresponding rule related information from input information of the user to be determined based on the priority determining rule, and carrying out priority ranking on all the users to be determined based on the rule related information and the corresponding priority determining rule to obtain a first priority ranking result; calculating the integrity value of the input information of the user to be determined, calculating the priority weight based on the integrity value, and determining a second priority ordering result based on the priority weight and the first priority ordering result; determining the final priority of the user to be determined based on the priority to be determined and the second priority sorting result; determining the interactive priority of the interactable user based on the consistent sequencing result in the user priority sequencing list and the final priority of the user to be determined;

wherein alpha is the integrity value of the input information of the user to be determined, i is the ith piece of input information of the user to be determined, n is the total number of pieces of input information contained in the input information of the user to be determined, y _i For a first total number of bytes, w, in the ith piece of sub-entry information of the user to be determined _i For a second total number of bytes, j, of offending bytes contained in the ith piece of sub-entry information of the user to be determined _i For a third total number of bytes, y, for which the attribute contained in the ith piece of sub-entry information of the user to be determined is inconsistent with the corresponding attribute of the sub-entry information _0i Mark corresponding to ith sub-input information of user to be determinedA quasictotal number of bytes;

calculating a priority weight based on the integrity value, comprising: