CN112434996A

CN112434996A - Cabinet grid distribution method, device and system of intelligent cabinet

Info

Publication number: CN112434996A
Application number: CN202110102481.7A
Authority: CN
Inventors: 施杰; 闵伟; 孙抗; 吴垒; 姚远
Original assignee: Lazas Network Technology Shanghai Co Ltd; Zhejiang Koubei Network Technology Co Ltd
Current assignee: Lazas Network Technology Shanghai Co Ltd; Zhejiang Koubei Network Technology Co Ltd
Priority date: 2021-01-26
Filing date: 2021-01-26
Publication date: 2021-03-02

Abstract

The application discloses a cabinet lattice distribution method, device and system of an intelligent cabinet, and relates to the technical field of information. The method comprises the following steps: scanning and recognizing an identification code on a target cabinet body in an intelligent cabinet by a client, wherein different cabinet bodies in the intelligent cabinet are respectively provided with corresponding identification codes; sending a storage request, wherein the storage request carries an identifier obtained by scanning a code, so that available cabinet lattices are preferentially allocated in a target cabinet body according to the cabinet lattice use condition of the target cabinet body matched with the identifier; first cabinet allocation information is received. This application can realize distributing available cabinet check preferentially in the cabinet body of depositing a user self position department, be convenient for deposit a user and look for the deposit a cabinet check of distribution, reduce the time of depositing a user and look for cabinet check, can improve the user and deposit an efficiency to can promote user's use and experience.

Description

Cabinet grid distribution method, device and system of intelligent cabinet

Technical Field

The present application relates to the field of information technology, and in particular, to a method, an apparatus, and a system for distributing cabinet lattices of an intelligent cabinet.

Background

The intelligent cabinet can be used to deposit and send an article, deposits a user and leaves article in the intelligent cabinet, and follow-up user's accessible of getting is got mode such as a sign indicating number, takes out the article of depositing in the intelligent cabinet.

At present, when a user stores a file in an intelligent cabinet, an intelligent cabinet system can identify distribution cabinet lattices according to the cabinet lattice, and particularly can randomly distribute idle cabinet lattices in the intelligent cabinet.

However, each intelligent cabinet usually includes a main cabinet and a plurality of auxiliary cabinets, and each main cabinet or each auxiliary cabinet usually has a width of about 1 to 2 meters and a height of about 2 meters, when the number of the auxiliary cabinets of the intelligent cabinet is large, for example, when 6 groups or more are provided, the user storage unit needs to search for the cabinet grid within a range of more than 10 meters, which is time-consuming, and when the number of the users accessing the unit is large, not only the user storage efficiency is affected, but also body collision, danger and the like are easily caused.

Disclosure of Invention

In view of this, the present application provides a cabinet grid allocation method, device and system for an intelligent cabinet, and mainly aims to improve technical problems that not only the storage efficiency of a user is affected, but also the body of the user is easily collided and dangers exist in the conventional technology.

According to one aspect of the application, a cabinet lattice allocation method of an intelligent cabinet is provided, which can be applied to a server side or an intelligent cabinet side, and the method comprises the following steps:

receiving a storage request of an intelligent cabinet sent by a client, wherein the storage request carries an identifier obtained by the client through code scanning identification;

inquiring the cabinet lattice use condition of a target cabinet body matched with the identification in one or more cabinet bodies of the intelligent cabinet;

preferentially distributing available cabinet lattices in the target cabinet body according to the use condition of the cabinet lattices;

and returning cabinet allocation information to the client.

According to another aspect of the present application, there is provided a cabinet allocation method for an intelligent cabinet, which is applicable to a client side, the method including:

scanning and recognizing identification codes on a target cabinet body in the intelligent cabinet, wherein the different cabinet bodies in the intelligent cabinet are respectively provided with corresponding identification codes;

sending a storage request, wherein the storage request carries an identifier obtained by code scanning identification, so that available cabinet lattices are preferentially allocated in a target cabinet body according to the cabinet lattice use condition of the target cabinet body matched with the identifier;

first cabinet allocation information is received.

According to another aspect of the present application, there is provided a cabinet grid allocation apparatus for an intelligent cabinet, which can be applied to a server or an intelligent cabinet, the apparatus including:

the receiving module is used for receiving a storage request of the intelligent cabinet sent by a client, wherein the storage request carries an identifier obtained by the client through code scanning identification;

the determining module is used for inquiring the cabinet lattice use condition of a target cabinet body matched with the identification in one or more cabinet bodies of the intelligent cabinet;

the distribution module is used for preferentially distributing available cabinet lattices in the target cabinet body according to the use condition of the cabinet lattices;

and the sending module is used for returning cabinet distribution information to the client.

According to still another aspect of the present application, there is provided a cabinet division distributing apparatus of an intelligent cabinet, which is applicable to a client side, the apparatus including:

the identification module is used for scanning and identifying identification codes on a target cabinet body in the intelligent cabinet, wherein the different cabinet bodies in the intelligent cabinet are respectively provided with corresponding identification codes;

the storage request carries an identifier obtained by code scanning identification, so that available cabinet lattices are preferentially allocated in the target cabinet body according to the cabinet lattice use condition of the target cabinet body matched with the identifier;

and the receiving module is used for receiving the first cabinet distribution information.

According to yet another aspect of the present application, there is provided a storage medium having stored thereon a computer program which, when executed by a processor, implements the above-described method of cabinet allocation for an intelligent cabinet.

According to yet another aspect of the present application, there is provided an electronic device, which may be a client device or a server device, wherein the client device includes a storage medium, a processor, and a computer program stored on the storage medium and running on the processor, and the processor executes the computer program to implement the above-mentioned method for allocating a shelf applicable to a smart cabinet on a client side. The server device comprises a storage medium, a processor and a computer program which is stored on the storage medium and can run on the processor, wherein the processor executes the computer program to realize the cabinet grid distribution method applicable to the intelligent cabinet at the server side or the intelligent cabinet side.

In accordance with yet another aspect of the present application, there is provided a cabinet grid distribution system for an intelligent cabinet, comprising: the client device and the server device.

By means of the technical scheme, compared with the traditional mode at present, the method, the device and the system for distributing the cabinet lattices of the intelligent cabinet can pre-arrange the corresponding identification codes on each cabinet body of the intelligent cabinet, when a user stores a product, the user can scan the identification codes on the target cabinet body at the position of the user through the identification codes, then a product storing request is sent, and the product storing request carries the identification of the target cabinet body obtained by scanning the codes, so that the available cabinet lattices can be preferentially distributed in the target cabinet body. Through this kind of mode of this application can realize preferentially distributing available cabinet check in the cabinet body of depositing a user self position department, be convenient for deposit a user and look for the deposit a cabinet check of distribution, reduce the time of depositing a user and look for cabinet check, can improve the user and deposit an efficiency to can promote user's use and experience. And when the number of the auxiliary cabinets of the intelligent cabinet is large, the number of the storage users is reduced, and the storage users can walk back and forth by searching the cabinet lattices in front of the cabinet body, so that the situations of physical collision of the users, danger and the like can be reduced.

The foregoing description is only an overview of the technical solutions of the present application, and the present application can be implemented according to the content of the description in order to make the technical means of the present application more clearly understood, and the following detailed description of the present application is given in order to make the above and other objects, features, and advantages of the present application more clearly understandable.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

fig. 1 is a schematic flowchart illustrating a cabinet allocation method for an intelligent cabinet according to an embodiment of the present application;

fig. 2 shows a schematic diagram of a model of an intelligent cabinet provided by an embodiment of the present application;

fig. 3 is a schematic flowchart illustrating a cabinet allocation method for an intelligent cabinet according to an embodiment of the present application;

fig. 4 is a schematic flow chart illustrating an example of a cabinet binding identification code provided by an embodiment of the present application;

fig. 5 is a schematic flowchart illustrating a cabinet allocation method for an intelligent cabinet according to an embodiment of the present application;

fig. 6 is a schematic flowchart illustrating an example application scenario provided in an embodiment of the present application;

fig. 7 is a schematic structural diagram illustrating a cabinet compartment distribution device of an intelligent cabinet according to an embodiment of the present application;

fig. 8 is a schematic structural diagram illustrating another cabinet compartment distribution device of an intelligent cabinet according to an embodiment of the present application;

fig. 9 shows a schematic structural diagram of a cabinet division distribution system of an intelligent cabinet provided in an embodiment of the present application.

Detailed Description

The present application will be described in detail below with reference to the accompanying drawings in conjunction with embodiments. It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict.

The method aims to solve the technical problems that the storage efficiency of a user is influenced, the body of the user is easy to collide, danger exists and the like in the conventional technology at present. The embodiment provides a cabinet grid allocation method for an intelligent cabinet, which is applicable to a client side of a storage user as shown in fig. 1, and the method includes:

step 101, a client scans and identifies an identification code on a target cabinet body in an intelligent cabinet.

The execution subject of the embodiment of the present invention may be a client device of a storage user, for example, an Application (APP) with a logistics storage function installed on a smart terminal such as a smart phone or a tablet computer, or an applet, a public number, a WEB Application, or the like. The storage user can be a distributor or other users needing storage, etc.

In this embodiment, the intelligent cabinet may include at least one set of cabinet body, and specifically may include: the intelligent cabinet comprises a main cabinet with a screen (equivalent to a group of cabinets), an auxiliary cabinet with only a lamp box and cabinet grids (equivalent to another group of cabinets), and the like, wherein the main cabinet and a plurality of auxiliary cabinets form the intelligent cabinet integrally under a general condition. The cabinet check can be used for depositing articles and taking out in the intelligent cabinet access cabinet, and has a numbered check opening, and the number of the cabinet checks in each group of cabinet bodies and the size of the cabinet checks are not limited. For example, as shown in fig. 2, a schematic diagram of a smart cabinet style is provided, which includes A, B, C, D four groups of cabinets, where a is a main cabinet with a screen, and B, C, D is a sub-cabinet with only a light box and a cabinet grid. The numbers 1 to 28 respectively represent the individual cabinet sections, i.e. the cabinet section numbers. Besides, the intelligent cabinet can also be an intelligent cabinet which is composed of a plurality of groups of auxiliary cabinets and the like.

In order to improve the storage efficiency of the user, identification codes capable of being identified by scanning codes can be preconfigured on different cabinets in the intelligent cabinet of the embodiment, for example, the identification codes can be configured at the cabinet light box, so that the different cabinets in the intelligent cabinet have respective corresponding identification codes. These identification codes may be one-dimensional, two-dimensional, or other multi-dimensional bar codes, etc. Each identification code can be pre-bound with the corresponding mapping relation of the cabinet body.

The target cabinet body can be a cabinet body where the identification code of the code is selected and scanned by the storage user in the intelligent cabinet, and the target cabinet body can be a certain cabinet body which can provide storage service in the intelligent cabinet.

Step 102, the client sends a storage request.

The storage request can be sent to a server of the intelligent cabinet, or to the intelligent cabinet local control device, where the server may be a server of the intelligent cabinet control system, and may be configured at the intelligent cabinet side or the cloud end side, and for convenience of description, the storage request may be sent to a background (such as the server or the intelligent cabinet local control device). The storage request sent by the client carries the identifier obtained by scanning the code, and further, the background preferentially allocates available cabinet lattices in the target cabinet body according to the cabinet lattice use condition of the target cabinet body matched with the identifier. The position of the target cabinet body can be regarded as the cabinet body where the current position of the storage user is located, the available cabinet lattices are preferentially distributed in the target cabinet body, the available cabinet lattices can be preferentially distributed in the cabinet body at the position of the storage user, the storage user can conveniently search the distributed storage cabinet lattices, the time for the storage user to search the cabinet lattices is reduced, and the storage efficiency of the user can be improved.

For example, after receiving the storage request, the server may determine, by querying the identifiers corresponding to the different cabinets in the intelligent cabinet, which identifier is corresponding to which cabinet the identifier carried in the storage request is. After the identification of the target cabinet body is determined, whether idle cabinet lattices exist in the target cabinet body is judged according to the use condition of the cabinet lattices of the target cabinet body (such as the occupation condition and the idle condition of each cabinet lattice in the target cabinet body), and if the idle cabinet lattices exist, one cabinet lattice is allocated in the idle cabinet lattices to serve as the current storage cabinet lattice.

And 103, receiving the first cabinet distribution information by the client.

The first cabinet allocation information may be cabinet allocation information returned to the client by the background, and if an available cabinet exists in the intelligent cabinet, the cabinet allocation information may include information of a number, a location, and the like of a specifically allocated cabinet, and if an available cabinet exists in the target cabinet, the allocated cabinet is a certain cabinet allocated in the target cabinet. And if no available cabinet grids exist in the intelligent cabinet, the cabinet grid distribution information can contain information of cabinet grid distribution failure caused by the fact that the intelligent cabinet is full or abnormal and the like.

Compared with the conventional mode, the cabinet lattice allocation method applicable to the intelligent cabinet provided by the embodiment can pre-arrange the corresponding identification codes on each cabinet body of the intelligent cabinet, when a user stores a product, the user can scan the identification codes on the target cabinet body at the position of the user, and then send a storage request, wherein the storage request carries the identification of the target cabinet body obtained by scanning the codes, so that the available cabinet lattices can be preferentially allocated in the target cabinet body. The mode can realize preferentially distributing the available cabinet lattices in the cabinet body at the position of the storage user, so that the storage user can search the distributed storage cabinet lattices conveniently, the time for searching the cabinet lattices by the storage user is reduced, the storage efficiency of the user can be improved, and the use experience of the user can be improved. And when the number of the auxiliary cabinets of the intelligent cabinet is large, the number of the storage users is reduced, and the storage users can walk back and forth by searching the cabinet lattices in front of the cabinet body, so that the situations of physical collision of the users, danger and the like can be reduced.

Further, as a refinement and an extension of the specific implementation of the above embodiment, another method for allocating a shelf applicable to a client-side intelligent cabinet is provided, as shown in fig. 3, where the method includes:

step 201, a client scans and identifies an identification code on a target cabinet body in the intelligent cabinet.

Different cabinets in the intelligence cabinet all have the identification code that corresponds separately on the different cabinets body. The identification codes corresponding to different cabinets in the intelligent cabinet are unique identification codes different from each other, and the unique identification codes are bound with mapping relations between the identifications of the cabinets corresponding to the intelligent cabinet in advance. To this embodiment, each cabinet body of intelligence cabinet binds corresponding identification code for the cabinet body has a one-to-one correspondence with the identification code, and every cabinet body all has the exclusive identification code of applying for the cabinet check.

For example, the binding process of the cabinet body (main and auxiliary cabinets) and the corresponding identification code is realized in advance. As shown in fig. 4, taking the identification code as a two-dimensional code as an example, a main cabinet list and a sub cabinet list of the intelligent cabinet are obtained first, and all the cabinets which can be used for storing articles are included in the list. And then binding two-dimensional codes at the lamp boxes of the cabinets, wherein the two-dimensional codes bound by each cabinet are unique two-dimensional codes different from each other, so that the two-dimensional codes bound by code scanning identification are directly locked, and specifically the two-dimensional code at the lamp box of which cabinet is scanned by a user to request storage.

It should be noted that, the two-dimensional code may bind, in addition to the identifier of the corresponding cabinet, the identifier of the intelligent cabinet in which the cabinet is located, so that when a subsequent client sends a storage request to the server, it is clear which intelligent cabinet is requested to open the cabinet, and which cabinet in the intelligent cabinet is preferentially allocated with the available cabinet grid.

Step 202, the client sends a storage request.

The storage request carries the identifier obtained by scanning the code, and further, the background preferentially allocates available cabinet lattices in the target cabinet body according to the cabinet lattice use condition of the target cabinet body matched with the identifier. The background firstly inquires whether available cabinet lattices exist in the target cabinet body, and if the available cabinet lattices exist in the target cabinet body, the available cabinet lattices are preferentially distributed in the target cabinet body.

Optionally, the identifier obtained by scanning the code may include an intelligent cabinet identifier and an intelligent cabinet identifier, and accordingly, the target cabinet is queried through the intelligent cabinet identifier and the intelligent cabinet identifier. If the intelligent cabinet needed to be used by the user at present is matched according to the intelligent cabinet identifier, and then the target cabinet needed to be used in the intelligent cabinet is matched according to the intelligent cabinet identifier. In addition to this optional manner, the target cabinet may be obtained by querying, by the background server, a mapping relationship stored in a preset storage location (e.g., a preset form, a preset database, etc.), where the preset storage location stores a mapping relationship among an identifier of the intelligent cabinet, identifiers of the cabinets in the intelligent cabinet, and identifiers of the cabinets in the cabinet, or stores a mapping relationship among identifiers of the cabinets in the intelligent cabinet and identifiers of the cabinets in the cabinet.

For example, if the background server is a platform server on the cloud side, the preset storage location may store a mapping relationship among the identifier of the smart cabinet, the identifier of each cabinet in the smart cabinet, and the identifier of each cabinet lattice in the cabinet. And subsequently, the mapping relation can be utilized, and the mark obtained by scanning the code is identified as a target cabinet body in the intelligent cabinet. Compare with traditional backstage only preserves the mapping relation between each cabinet check sign in intelligent cabinet sign and the intelligent cabinet, the cabinet body that a user swept the sign indicating number is deposited to the possible accurate discernment of this embodiment, and then can realize distributing available cabinet check in the cabinet body of depositing a user self position department preferentially, is convenient for deposit a user and seeks the deposit cabinet check of distribution, reduces the time that a user seeks cabinet check, can improve the user and deposit an efficiency.

For another example, if the background server is a server on the side of the intelligent cabinet, the preset storage location may store the identifier of each cabinet in the intelligent cabinet and the mapping relationship between the identifiers of each cabinet grid in the cabinet. And subsequently, the mapping relation can be utilized, and the mark obtained by scanning the code is identified as a target cabinet body in the intelligent cabinet. Compare with the mode that only has preserved each cabinet check sign in the intelligent cabinet in traditional backstage, the cabinet body that a yard was swept to the user of accomplishing accurate discernment to deposit can be accomplished to this embodiment, and then can realize distributing available cabinet check in the cabinet body of depositing user self position department in advance, the deposit cabinet check of the distribution of being convenient for deposit the user and seek.

Step 203, the client receives the first cabinet allocation information.

Illustratively, step 203 may specifically include: if available cabinet lattices exist in the target cabinet body, receiving available cabinet lattice information distributed in the target cabinet body; if there are no available shelves in the target cabinet and there are available shelves in the neighboring cabinet of the target cabinet, then available shelf information distributed in the neighboring cabinet of the target cabinet is received.

In this embodiment, the available bin is preferentially allocated in the target cabinet body scanned by the user, and if there is no available bin in the target cabinet body, it may be determined whether there is an available bin in the neighboring bin of the target cabinet body, and if there is an available bin in the neighboring bin, the available bin may be allocated therein for the storage user. Through the optional mode, even if the cabinet body of the current position of the user does not have free available cabinet lattices, the available cabinet lattices are distributed in the cabinet body of the adjacent position of the user as far as possible, so that the time for searching the distribution cabinet lattices by the user can be reduced, the user can conveniently find the distributed cabinet lattices in time near the identity, and the storage efficiency of the user can be improved.

Alternatively, the adjacent cabinet of the target cabinet may be a cabinet adjacent to the target cabinet or a cabinet having a distance less than a preset distance threshold. The preset distance threshold value can be set according to the actual scene requirements, the available cabinet lattices can be preferentially distributed near the position of the storage user as far as possible through the setting of the threshold value, the traveling distance for searching the distribution cabinet lattices by the user is reduced, the distributed cabinet lattices are conveniently searched as far as possible, and therefore the storage efficiency of the user is improved.

When first cabinet grid distribution information is received, in order to facilitate a storage user to know the cabinet grid distribution condition at the first time, prompt information for opening the door of the cabinet grid can be output according to the first cabinet grid distribution information. The output may be in the form of text, pictures, audio, video, lights, vibrations, etc. For example, a user can display that a storage case is opened at a mobile phone end, and can output a corresponding sound prompt to further indicate the storage user to store the storage case correspondingly, and the storage is determined to be completed after the user closes the storage case.

In a specific application scenario, a storage user is likely to store more than one storage, and may store more than one storage, and if the traditional cabinet allocation manner is adopted, the allocated cabinet and the last allocated cabinet may be far apart, so that the storage user may cross and come before the whole intelligent cabinet. The on-site order is disordered, and the storage efficiency of the storage user and the pickup efficiency of the pickup user are greatly reduced. The scheme of the embodiment is based on the principle of near distribution, and can distribute the appropriate cabinet lattices which are close to the users and have no position influence among the users. The process shown in steps 204 to 205a, 205b may be performed in particular.

Step 204, the client sends a continuous storage request.

For example, when a storage user needs to store a plurality of bills in the smart cabinet, after the first bill is stored in the manner shown in the above steps 201 to 203, the storage user may click the persistent storage of the applet and send a persistent storage request.

The identity information of the storage user can be carried in the continuous storage request, so that the cabinet lattice information distributed by the storage user in the last storage can be inquired according to the identity information of the storage user. And then can be preferred deposit the available cabinet check of distribution in the cabinet body of a distribution last time, reduce and deposit the distance of marcing of a user twice in-process of depositing, in time find the cabinet check of distribution when convenience of customers deposits a piece once more, save the length of seeking the cabinet check of distribution, can improve the efficiency that the user deposited a piece once more. Even if the cabinet body of the last storage and distribution does not have idle available cabinet lattices, the available cabinet lattices can be preferentially distributed in the cabinet body near the cabinet body, so that the distributed cabinet lattices are conveniently searched by a user as much as possible, and the time consumed for searching is saved. As shown in

steps

205a and 205b, the following is illustrated in two cases:

and step 205a, if the cabinet lattice of the last storage and distribution of the storage user has an available cabinet lattice in the cabinet body, receiving second cabinet lattice distribution information.

The second cabinet distribution information can be available cabinet information distributed in the cabinet body where the cabinet distributed by the storage user last time is located.

And a step 205b parallel to the step 205a, if the cabinet body where the cabinet lattice allocated by the storage user for the last storage does not have an available cabinet lattice, and the cabinet body adjacent to the cabinet body where the cabinet lattice allocated by the storage user for the last storage does not have an available cabinet lattice, receiving third cabinet lattice allocation information.

The third cabinet distribution information can be available cabinet information in a cabinet body adjacent to the cabinet body where the cabinet distributed by the storage user last time is located.

Optionally, the cabinet body adjacent to the cabinet body where the cabinet lattice last distributed by the storage user is located is the cabinet body adjacent to the cabinet body where the cabinet lattice last distributed by the storage user is located, or the distance between the adjacent cabinet bodies and the cabinet lattice last distributed by the storage user is smaller than the predetermined distance threshold. The preset distance threshold value can be set according to the actual scene requirements, and through the setting of the threshold value, when the storage user continuously stores the parts, the available cabinet lattices can be preferentially distributed near the position of the storage user as far as possible, so that the travelling distance of the user for searching the distribution cabinet lattices is reduced, the distributed cabinet lattices can be conveniently searched as far as possible, and the efficiency of storing the parts by the user is improved.

Further optionally, the cabinet allocated in the second cabinet allocation information or the third cabinet allocation information may be an available cabinet allocated in the first cabinet allocation information, where the available cabinet is closest to the cabinet allocated in the first cabinet allocation information. For example, when the storage cabinet lattices are allocated again, available cabinet lattices are allocated preferentially near the position of the storage user, and available cabinet lattices which are closest to the last allocation cabinet lattices are also allocated as much as possible, so that the user can continuously store the parts without moving the body basically or with small amplitude, the action change amplitude between the two previous times of storage is small, the storage efficiency can be improved, and the labor can be saved.

For example, as shown in fig. 2, in the intelligent cabinet, a storage user scans a two-dimensional code on a light box of a C-group cabinet body, sends a storage request, where the storage request may carry two-dimensional code information of the C-group cabinet body, and a background preferentially allocates available cabinet lattices according to the C-group cabinet body, so that even if there are no available cabinet lattices in the C-group cabinet body, the available cabinet lattices may be preferentially allocated in adjacent cabinet bodies of the B-group and the D-group. The cabinet lattices distributed by the first single storage unit are 18 # cabinet lattices in the C group of cabinet bodies. The bins may also be preferentially assigned among the group C cabinets on a continuing basis, and if there are no available bins in the group C cabinets, the available bins may be preferentially assigned among the adjacent groups B and D. If the group C is full, free available cabinet lattices (No. 8 and No. 10 cabinet lattices) exist in the group B cabinet body, and free available cabinet lattices (No. 22 cabinet lattices) exist in the group D cabinet body, and the 22 cabinet lattices closest to the 18 number can be selected as the cabinet lattices allocated by the second single storage component because the last single storage component is allocated with the No. 18 cabinet lattices.

Compared with the conventional mode, the cabinet lattice distribution method applicable to the intelligent cabinet provided by the embodiment preferentially distributes the available cabinet lattices in the cabinet body at the position of the storage user, so that the storage user can conveniently search the distributed storage cabinet lattices, the time for searching the cabinet lattices by the storage user is reduced, the storage efficiency of the user can be improved, and the use experience of the user can be improved.

The content of the foregoing embodiment is a cabinet allocation processing procedure of an intelligent cabinet described at a client side, and further, to fully illustrate an implementation of this embodiment, this embodiment further provides another cabinet allocation method of an intelligent cabinet, which can be applied to a server side or an intelligent cabinet side, as shown in fig. 5, where the method includes:

step 301, receiving a storage request of the intelligent cabinet sent by the client.

The execution main body of the embodiment of the present invention can be a background for storing and processing the file request of the client, and can be a server or a local control device of the intelligent cabinet, etc. The storage request carries an identifier obtained by the client through code scanning identification, and at least one cabinet body in the intelligent cabinet is provided with a corresponding identifier.

Step 302, inquiring the cabinet lattice use condition of the target cabinet body matched with the identification in the storage request in one or more cabinet bodies of the intelligent cabinet.

There may be multiple optional manners when the identifier obtained by scanning the code carried in the request matches the target cabinet, and as an optional manner, the identifier includes an intelligent cabinet identifier and an intelligent cabinet identifier, and the corresponding step 302 may specifically include: firstly, acquiring an intelligent cabinet corresponding to the intelligent cabinet identifier; then acquiring a cabinet body corresponding to the intelligent cabinet body identification from the intelligent cabinet corresponding to the intelligent cabinet identification as a target cabinet body; after the target cabinet body is locked, the use condition of the cabinet lattice of the target cabinet body can be inquired.

As another alternative, step 302 may specifically include: firstly, determining an identifier carried in a storage request as an identifier of a target cabinet body by inquiring a mapping relation stored in a preset storage position (such as a preset form or a database) wherein the preset storage position stores a mapping relation among an intelligent cabinet identifier, identifiers of all cabinet bodies in an intelligent cabinet and identifiers of all cabinet lattices in the cabinet body, or stores a mapping relation among the identifiers of all cabinet bodies in the intelligent cabinet and the identifiers of all cabinet lattices in the cabinet body; similarly, after the target cabinet body is locked, the use condition of the cabinet lattice of the target cabinet body can be inquired.

And 303, preferentially distributing available cabinet lattices in the target cabinet body according to the cabinet lattice using condition of the target cabinet body.

For example, the use condition of the cabinet lattice of the target cabinet body (such as the occupation condition and the idle condition of each cabinet lattice in the target cabinet body) is obtained, whether available cabinet lattices exist in the target cabinet body is inquired according to the use condition of the cabinet lattice, and if yes, the available cabinet lattices are distributed, so that the purpose of preferentially distributing the available cabinet lattices in the target cabinet body is achieved.

Optionally, step 303 may specifically include: and preferentially distributing the available cabinet lattices in the target cabinet body or the adjacent cabinet body of the target cabinet body according to the use condition of the cabinet lattices of the target cabinet body. For example, the allocation priority may be set such that a cabinet compartment is allocated in the target cabinet first, if there is no free available cabinet compartment in the target cabinet, a cabinet compartment may be allocated in a neighboring cabinet compartment of the target cabinet, if there is no free available cabinet compartment in a neighboring cabinet compartment, a cabinet compartment may be allocated in a cabinet closer to the target cabinet as possible, and so on. By setting the distribution priority, available cabinet lattices can be preferentially distributed near the position of the storage user as much as possible, the travelling distance of the user for searching the distribution cabinet lattices is reduced, the distributed cabinet lattices are conveniently searched as much as possible, and the storage efficiency of the user is improved.

For example, the above preferentially allocating the available cabinet lattices in the target cabinet or the adjacent cabinet of the target cabinet according to the cabinet lattice usage condition of the target cabinet specifically may include: inquiring whether idle available cabinet lattices exist in the target cabinet body or not by using the identification of the target cabinet body; if the target cabinet body has idle available cabinet lattices, distributing the available cabinet lattices in the target cabinet body; if the free available cabinet lattices do not exist in the target cabinet body, inquiring whether the free available cabinet lattices exist in the adjacent cabinet body of the target cabinet body, and when the free available cabinet lattices exist in the adjacent cabinet body of the target cabinet body, distributing the available cabinet lattices in the adjacent cabinet body of the target cabinet body.

The adjacent cabinet of the target cabinet may be a cabinet that is contiguous with the target cabinet or is a distance less than a preset distance threshold. The preset distance threshold value can be set according to the actual scene requirements, the available cabinet lattices can be preferentially distributed near the position of the storage user as far as possible through the setting of the threshold value, the traveling distance for searching the distribution cabinet lattices by the user is reduced, the distributed cabinet lattices are conveniently searched as far as possible, and therefore the storage efficiency of the user is improved.

And step 304, returning cabinet allocation information to the client.

Optionally, the storage request sent by the client may also carry identity information of the storage user, and before returning the cabinet allocation information to the client, the method of this embodiment further includes: judging whether the storage user has the authority to acquire order information of the storage user according to the identity information of the storage user; if the order information of the storage user is authorized to be acquired, determining cabinet lattice distribution information according to the order information of the current to-be-stored item and in combination with the storage packaging specification standard of the intelligent cabinet; and if the order information of the storage user is not acquired, determining cabinet grid allocation information according to a preset default cabinet grid allocation standard.

In the process of distributing cabinet lattices, in order to realize accurate distribution to proper available cabinet lattices, if a background has authority to inquire the order information of a corresponding storage of a user according to the identity information of the user to be stored, the terminal position information of the storage user and the intelligent cabinet information can be obtained to carry out matching verification so as to determine the order information of the storage in the intelligent cabinet, and the distribution cabinet lattice information is determined by combining the storage packaging specification standard. Through the optional mode, the order information of the stored items in the current intelligent cabinet can be automatically judged by the background, and a distributor does not need to manually search the distribution addresses of all the orders one by one, so that the item storage efficiency is improved, and the accurate distribution of logistics is realized. And the number of the cabinet grids required by the order and the size of the cabinet grids (such as large grid opening, middle grid opening, small grid opening and the like) can be accurately distributed according to the storage packaging specification standard, so that the distribution accuracy of the proper cabinet grids is improved.

In addition to the above optional manner, the background may query the order information of the storage corresponding to the user without permission (for example, order data in another platform cannot be acquired due to different platforms) according to the identity information of the storage user, and at this time, in order to help quickly implement cabinet allocation, cabinet allocation may be performed according to a preset default allocation standard. For example, the default cabinet grid allocation standard may be that the default allocation number is 1 cabinet grid, and the cabinet grid size is selected from small cabinet grids (the cabinet grid size is divided into large, medium and small cells); or the default cabinet grid distribution standard can be preset to be 1 cabinet grid in number, the size of each cabinet grid is selected to be a middle cabinet grid, and the like. The default cabinet grid allocation standard can be preset according to actual requirements. Through this kind of optional mode, can realize quick cabinet check distribution, improve the efficiency of cabinet check distribution, and then can improve and deposit a efficiency.

For convenience of understanding of the specific implementation process of the method in each embodiment, the following application scenarios are given, but not limited to:

taking a meal storage scene as an example, a great amount of grids may exist in a meal cabinet at present, and due to randomness of a food delivery person (knight) when applying for the cabinet grids, the grid finding is very difficult after applying for the cabinet grids if the number of the grids is large, the experience of selling into the cabinet in the whole of the knight at peak time is very influenced, and the efficiency of putting the intelligent cabinet in a single mode by the knight is influenced.

In order to solve the above problem, the method of this embodiment is applied to bind the corresponding two-dimensional code to each cabinet body of the intelligent cabinet in advance, so that the cabinet bodies and the two-dimensional codes have a one-to-one correspondence relationship, and each cabinet has the two-dimensional code of the exclusive application cabinet lattice. The two-dimensional code of the vice cabinet of sign indicating number intelligence cabinet is swept to the knight, and the system priority assignment knight is swept the vice cabinet that the sign indicating number corresponds and is carried out the distribution of cabinet check, under the circumstances that can not distribute, can distribute the intelligence cabinet that this vice cabinet is neighbouring, improves the experience that the rider applied for the cabinet check and gone into the cabinet. The specific implementation flow can be as shown in fig. 6. Firstly, a knight code scanning indication storage part acquires two-dimensional code information obtained by code scanning identification; then, acquiring corresponding intelligent cabinet lattice information according to the two-dimension code information; and inquiring whether the auxiliary cabinet corresponding to the two-dimension code information has idle cabinet lattices, if so, applying for the cabinet lattices in the auxiliary cabinet, if not, inquiring whether the adjacent auxiliary cabinet has the idle cabinet lattices, and if the adjacent auxiliary cabinet finds the idle cabinet lattices, allocating the cabinet lattices.

Through using above-mentioned scheme, two-dimensional code and this pair cabinet are bound in advance on the intelligence cabinet lamp house, form and bind the relation, and the rider scans two-dimensional code on the intelligence cabinet lamp house, applies for the cabinet check, and the system can be according to the rider and scan the two-dimensional code of sign indicating number and acquire intelligence cabinet information, vice cabinet information, perception rider current position of standing, carries out to intelligence cabinet check distribution. The vice cabinet of the intelligent cabinet of sign indicating number is swept to preferential distribution rider, perhaps vice cabinet both sides vice cabinet reduces the rider and seeks the time of cabinet check, improves the efficiency that the cabinet was gone into in the takeaway of rider, improves the experience that the rider used intelligent cabinet.

Further, as a specific implementation of the method shown in fig. 1, the present embodiment provides a cabinet allocation apparatus applicable to a client-side intelligent cabinet, as shown in fig. 7, the apparatus includes: identification module 41, sending module 42, receiving module 43.

The identification module 41 is used for scanning and identifying identification codes on a target cabinet body in the intelligent cabinet, wherein the different cabinet bodies in the intelligent cabinet are respectively provided with corresponding identification codes;

the sending module 42 is configured to send a storage request, where the storage request carries an identifier obtained by code scanning identification, so that an available cabinet lattice is preferentially allocated in a target cabinet according to a cabinet lattice use condition of the target cabinet matched with the identifier;

and a receiving module 43, configured to receive the first cabinet allocation information.

In a specific application scenario, optionally, the identifier includes an intelligent cabinet identifier and an intelligent cabinet identifier, and the target cabinet is queried through the intelligent cabinet identifier and the intelligent cabinet identifier; or the target cabinet body is inquired through a mapping relation stored in a preset storage position, wherein the preset storage position stores a mapping relation among the intelligent cabinet identification, the identification of each cabinet body in the intelligent cabinet and the identification of each cabinet grid in the cabinet body, or stores a mapping relation among the identification of each cabinet body in the intelligent cabinet and the identification of each cabinet grid in the cabinet body.

In a specific application scenario, the receiving module 43 is specifically configured to receive available cabinet lattice information allocated in the target cabinet body if the available cabinet lattice exists in the target cabinet body; if no available cabinet lattice exists in the target cabinet and an available cabinet lattice exists in the adjacent cabinet of the target cabinet, receiving available cabinet lattice information distributed in the adjacent cabinet of the target cabinet.

In a specific application scenario, optionally, the adjacent cabinet of the target cabinet is a cabinet adjacent to the target cabinet or a cabinet with a distance smaller than a preset distance threshold.

In a specific application scenario, the sending module 42 is further configured to send a continuous storage request, where the continuous storage request carries identity information of a storage user, so as to query, according to the identity information, cabinet information allocated to the last storage of the storage user;

the receiving module 43 is further configured to receive second cabinet lattice allocation information if an available cabinet lattice exists in the cabinet body where the cabinet lattice allocated by the last storage and allocation of the storage user is located, where the second cabinet lattice allocation information is available cabinet lattice information allocated in the cabinet body where the cabinet lattice allocated by the last storage and allocation of the storage user is located; and if the cabinet body where the cabinet lattices allocated by the storage user last time do not have available cabinet lattices and the cabinet body adjacent to the cabinet body where the cabinet lattices allocated by the storage user last time do exist available cabinet lattices, receiving third cabinet lattice allocation information, wherein the third cabinet lattice allocation information is available cabinet lattice information in the cabinet body adjacent to the cabinet body where the cabinet lattices allocated by the storage user last time are located.

In a specific application scenario, optionally, the cabinet body adjacent to the cabinet body where the cabinet lattice last distributed by the storage user is located is the cabinet body adjacent to the cabinet body where the cabinet lattice last distributed by the storage user is located, or the distance between the adjacent cabinet bodies and the cabinet body is smaller than a predetermined distance threshold.

In a specific application scenario, optionally, the cabinet lattice allocated in the second cabinet lattice allocation information or the third cabinet lattice allocation information is an available cabinet lattice allocated in the first cabinet lattice allocation information and having the closest cabinet lattice distance.

In a specific application scenario, the apparatus further comprises: an output module;

and the output module is used for outputting the prompt information of opening the cabinet lattice according to the first cabinet lattice distribution information after receiving the first cabinet lattice distribution information.

It should be noted that other corresponding descriptions of the functional units related to the cabinet allocation apparatus applicable to the intelligent cabinet at the user client side provided in this embodiment may refer to the corresponding descriptions of the methods in fig. 1 and fig. 3, and are not described herein again.

Further, as a specific implementation of the method shown in fig. 5, an embodiment of the present application provides a cabinet grid allocation apparatus applicable to a server or an intelligent cabinet side of an intelligent cabinet, as shown in fig. 8, the apparatus includes: a receiving module 51, a determining module 52, an allocating module 53, and a transmitting module 54.

The receiving module 51 is configured to receive a storage request of an intelligent cabinet sent by a client, where the storage request carries an identifier obtained by the client through code scanning identification, and at least one cabinet body in the intelligent cabinet has a corresponding identifier;

the determining module 52 is configured to query the cabinet lattice usage of a target cabinet body, which is matched with the identifier, in one or more cabinet bodies of the intelligent cabinet;

the distribution module 53 is used for preferentially distributing available cabinet lattices in the target cabinet body according to the use condition of the cabinet lattices;

and a sending module 54, configured to return the cabinet allocation information to the client.

In a specific application scenario, the identifier includes an intelligent cabinet identifier and an intelligent cabinet body identifier; the determining module 52 is specifically configured to obtain an intelligent cabinet corresponding to the intelligent cabinet identifier; acquiring a cabinet body corresponding to the intelligent cabinet body identification as the target cabinet body from the intelligent cabinet corresponding to the intelligent cabinet body identification; and inquiring the use condition of the cabinet lattice of the target cabinet body.

In a specific application scenario, the determining module 52 is further configured to determine, by querying a mapping relationship stored in a preset storage location, that the identifier is an identifier of a target cabinet, where the preset storage location stores a mapping relationship among an identifier of an intelligent cabinet, identifiers of cabinets in the intelligent cabinet, and identifiers of cabinets in the cabinet, or stores a mapping relationship among identifiers of cabinets in the intelligent cabinet and identifiers of cabinets in the cabinet; and inquiring the use condition of the cabinet lattice of the target cabinet body.

The distribution module 53 is specifically configured to preferentially distribute available cabinets in the target cabinet or an adjacent cabinet of the target cabinet according to the use condition of the cabinet of the target cabinet.

In a specific application scenario, the allocating module 53 is further specifically configured to query whether an available vacant cabinet lattice exists in the target cabinet by using the cabinet lattice usage condition of the target cabinet; if the target cabinet body has idle available cabinet lattices, distributing the available cabinet lattices in the target cabinet body; if the free available cabinet lattices do not exist in the target cabinet body, inquiring whether the free available cabinet lattices exist in the adjacent cabinet body of the target cabinet body, and when determining that the free available cabinet lattices exist in the adjacent cabinet body of the target cabinet body, allocating the available cabinet lattices in the adjacent cabinet body of the target cabinet body.

In a specific application scenario, optionally, the storage request further carries identity information of a storage user, and the apparatus further includes: a judgment module;

the judging module is used for judging whether the client has the authority to acquire the order information of the storage user according to the identity information before returning the cabinet distribution information to the client;

the determining module 52 is further configured to determine cabinet lattice allocation information according to the order information of the current to-be-stored item and in combination with the storage package specification standard of the intelligent cabinet if the storage user has the right to acquire the order information of the storage user; and if the order information of the storage user is not acquired, determining cabinet grid allocation information according to a preset default cabinet grid allocation standard.

It should be noted that other corresponding descriptions of the functional units related to the cabinet grid allocation apparatus of the intelligent cabinet applicable to the server or the intelligent cabinet side provided in this embodiment may refer to the corresponding description of the method in fig. 5, and are not described herein again.

Based on the methods shown in fig. 1 and fig. 3, correspondingly, the present application further provides a storage medium, on which a computer program is stored, and when the computer program is executed by a processor, the method for allocating the cabinet, which is applicable to the intelligent cabinet on the user client side, is implemented as shown in fig. 1. Based on the method shown in fig. 5, an embodiment of the present application further provides another storage medium, on which a computer program is stored, and the computer program, when executed by a processor, implements the above-mentioned method for allocating shelves of the intelligent cabinet applicable to the server or the intelligent cabinet side shown in fig. 5.

Based on such understanding, the technical solution of the present application may be embodied in the form of a software product, which may be stored in a non-volatile storage medium (which may be a CD-ROM, a usb disk, a removable hard disk, etc.), and includes several instructions for enabling a computer device (which may be a personal computer, a server, or a network device, etc.) to execute the method of the embodiments of the present application.

Based on the methods shown in fig. 1 and fig. 3 and the virtual device embodiment shown in fig. 7, in order to achieve the above object, an embodiment of the present application further provides a client device, which may specifically be a tablet computer, a smart phone, a smart watch, a smart bracelet, or other network devices, and the client device includes a storage medium and a processor; a storage medium for storing a computer program; a processor for executing a computer program to implement the above-described shelf allocation method applicable to the smart cabinet on the user client side as shown in fig. 1 and 3.

Based on the method shown in fig. 5 and the virtual device embodiment shown in fig. 8, in order to achieve the above object, the present application embodiment further provides a server device, which may specifically be a server, a computer device, an intelligent cabinet management device, and the like. The apparatus includes a storage medium and a processor; a storage medium for storing a computer program; a processor for executing a computer program to implement the above-mentioned method for allocating a shelf of an intelligent cabinet applicable to a server or an intelligent cabinet side as shown in fig. 5.

Optionally, both the two entity devices may further include a user interface, a network interface, a camera, a Radio Frequency (RF) circuit, a sensor, an audio circuit, a WI-FI module, and the like. The user interface may include a Display screen (Display), an input unit such as a keypad (Keyboard), etc., and the optional user interface may also include a USB interface, a card reader interface, etc. The network interface may optionally include a standard wired interface, a wireless interface (e.g., WI-FI interface), etc.

Those skilled in the art will appreciate that the physical device structure of the client device and the server device provided in the present embodiment does not constitute a limitation to the two physical devices, and may include more or less components, or combine some components, or arrange different components.

The storage medium may further include an operating system and a network communication module. The operating system is a program that manages the hardware and software resources of the two physical devices described above, supporting the operation of the information processing program as well as other software and/or programs. The network communication module is used for realizing communication among components in the storage medium and communication with other hardware and software in the information processing entity device.

Based on the above, further, the embodiment of the present application also provides a cabinet grid distribution system of an intelligent cabinet, as shown in fig. 9, the system includes a server device 61, a client device 62; the server device 61 may be specifically configured on the cloud side, or on the smart cabinet 63 side, or the like.

Therein, the client device 62 may be used to perform the method as shown in fig. 1 and 3, and the server device 61 may be used to perform the method as shown in fig. 5.

The client device 62 can be used for scanning and identifying an identification code on a target cabinet body in the intelligent cabinet 63, wherein different cabinet bodies in the intelligent cabinet 63 have respective corresponding identification codes; and sending a storage request to the server device 61, wherein the storage request carries the identifier obtained by scanning the code.

The server device 61 is configured to receive a storage request of the intelligent cabinet 63 sent by the client device 62, where the storage request carries an identifier obtained by the client through code scanning identification; inquiring the cabinet lattice use condition of a target cabinet body matched with the identification in one or more cabinet bodies of the intelligent cabinet; preferentially distributing available cabinet lattices in the target cabinet body according to the use condition of the cabinet lattices of the target cabinet body; the bin assignment information is returned to the client device 62.

Through the above description of the embodiments, those skilled in the art will clearly understand that the present application can be implemented by software plus a necessary general hardware platform, and can also be implemented by hardware. Through the technical scheme who uses this embodiment, compare with present traditional mode, this embodiment can arrange respective corresponding identification code in advance on each cabinet body of intelligence cabinet, and the code is swept to the identification code on the target cabinet body of self position department to the accessible when the user is depositing, and then sends and deposit the request, carries the sign of this target cabinet body in the request of depositing for can distribute available cabinet check in this target cabinet body in advance. The mode can realize preferentially distributing the available cabinet lattices in the cabinet body at the position of the storage user, so that the storage user can search the distributed storage cabinet lattices conveniently, the time for searching the cabinet lattices by the storage user is reduced, the storage efficiency of the user can be improved, and the use experience of the user can be improved.

Those skilled in the art will appreciate that the figures are merely schematic representations of one preferred implementation scenario and that the blocks or flow diagrams in the figures are not necessarily required to practice the present application. Those skilled in the art will appreciate that the modules in the devices in the implementation scenario may be distributed in the devices in the implementation scenario according to the description of the implementation scenario, or may be located in one or more devices different from the present implementation scenario with corresponding changes. The modules of the implementation scenario may be combined into one module, or may be further split into a plurality of sub-modules.

The above application serial numbers are for description purposes only and do not represent the superiority or inferiority of the implementation scenarios. The above disclosure is only a few specific implementation scenarios of the present application, but the present application is not limited thereto, and any variations that can be made by those skilled in the art are intended to fall within the scope of the present application.

Claims

1. A cabinet lattice distribution method of an intelligent cabinet is characterized by comprising the following steps:

and returning cabinet allocation information to the client.

2. The method of claim 1, wherein the identification comprises a smart cabinet identification and a smart cabinet body identification;

the querying of the cabinet lattice use condition of the target cabinet body matched with the identifier in the one or more cabinet bodies of the intelligent cabinet specifically includes:

acquiring an intelligent cabinet corresponding to the intelligent cabinet identifier;

acquiring a cabinet body corresponding to the intelligent cabinet body identification as the target cabinet body from the intelligent cabinet corresponding to the intelligent cabinet body identification;

and inquiring the use condition of the cabinet lattice of the target cabinet body.

3. The method according to claim 1, wherein the querying for the use of the cabinet lattice of the target cabinet matching the identifier from among the one or more cabinets of the smart cabinet specifically comprises:

determining the identifier as the identifier of the target cabinet body by inquiring a mapping relation stored in a preset storage position, wherein the preset storage position stores the mapping relation among the intelligent cabinet identifier, the identifier of each cabinet body in the intelligent cabinet and the identifier of each cabinet lattice in the cabinet body, or stores the mapping relation among the identifier of each cabinet body in the intelligent cabinet and the identifier of each cabinet lattice in the cabinet body;

4. The method according to claim 1, wherein the preferentially allocating available bins in the target cabinet according to the bin usage comprises:

inquiring whether the target cabinet body has idle available cabinet lattices or not by utilizing the use condition of the cabinet lattices;

if the target cabinet body has idle available cabinet lattices, distributing the available cabinet lattices in the target cabinet body;

if the free available cabinet lattices do not exist in the target cabinet body, inquiring whether the free available cabinet lattices exist in the adjacent cabinet body of the target cabinet body, and when determining that the free available cabinet lattices exist in the adjacent cabinet body of the target cabinet body, allocating the available cabinet lattices in the adjacent cabinet body of the target cabinet body.

5. The method according to claim 1, wherein the storage request further carries identity information of a storage user;

before the returning of the counter allocation information to the client, the method further comprises:

judging whether the authority is available to acquire the order information of the storage user or not according to the identity information;

if the order information of the storage user is authorized to be acquired, cabinet lattice distribution information is determined according to the order information of the current to-be-stored piece and in combination with the storage packaging specification standard of the intelligent cabinet;

and if the order information of the storage user is not acquired, determining cabinet grid allocation information according to a preset default cabinet grid allocation standard.

6. A cabinet lattice distribution method of an intelligent cabinet is characterized by comprising the following steps:

first cabinet allocation information is received.

7. The method of claim 6, wherein the identification comprises a smart cabinet identification and a smart cabinet body identification, and the target cabinet body is queried by the smart cabinet identification and the smart cabinet body identification; alternatively, the first and second electrodes may be,

the target cabinet body is inquired through a mapping relation stored in a preset storage position, wherein the mapping relation among the intelligent cabinet identification, the identification of each cabinet body in the intelligent cabinet and the identification of each cabinet grid in the cabinet body is stored in the preset storage position, or the mapping relation among the identification of each cabinet body in the intelligent cabinet and the identification of each cabinet grid in the cabinet body is stored in the preset storage position.

8. The method according to claim 6, wherein the receiving the first counter allocation information specifically comprises:

if available cabinet lattices exist in the target cabinet body, receiving available cabinet lattice information distributed in the target cabinet body;

if the available cabinet lattices do not exist in the target cabinet body and the available cabinet lattices exist in the adjacent cabinet bodies of the target cabinet body, receiving available cabinet lattice information distributed in the adjacent cabinet bodies of the target cabinet body, wherein the adjacent cabinet bodies of the target cabinet body are adjacent to the target cabinet body or the distance between the adjacent cabinet bodies of the target cabinet body and the target cabinet body is smaller than a preset distance threshold value.

9. The method of claim 6, wherein after said receiving first bin allocation information, the method further comprises:

sending a continuous storage request, wherein the continuous storage request carries identity information of a storage user, so that cabinet lattice information distributed by the last storage of the storage user is inquired according to the identity information;

if the cabinet body where the cabinet lattice allocated by the storage user for the last storage exists available cabinet lattices, receiving second cabinet lattice allocation information, wherein the second cabinet lattice allocation information is the available cabinet lattice information allocated in the cabinet body where the cabinet lattice allocated by the storage user for the last storage exists;

and if the cabinet body where the cabinet lattices allocated by the storage user last time do not have available cabinet lattices and the cabinet body adjacent to the cabinet body where the cabinet lattices allocated by the storage user last time do exist available cabinet lattices, receiving third cabinet lattice allocation information, wherein the third cabinet lattice allocation information is available cabinet lattice information in the cabinet body adjacent to the cabinet body where the cabinet lattices allocated by the storage user last time are located.

10. The method according to claim 9, wherein the cabinet adjacent to the cabinet where the cabinet last stored and dispensed by the storage user is located is the cabinet adjacent to the cabinet where the cabinet last stored and dispensed by the storage user is located or the distance between the adjacent cabinets is smaller than a predetermined distance threshold;

the cabinet lattice allocated in the second cabinet lattice allocation information or the third cabinet lattice allocation information is the available cabinet lattice allocated in the first cabinet lattice allocation information and closest to the cabinet lattice.

11. A cabinet check distribution device of an intelligent cabinet, comprising:

12. A cabinet check distribution device of an intelligent cabinet, comprising:

13. A storage medium on which a computer program is stored, which computer program, when being executed by a processor, carries out a method of bin allocation of a smart bin according to any one of claims 1 to 10.

14. An electronic device comprising a storage medium, a processor and a computer program stored on the storage medium and executable on the processor, wherein the processor implements the method of allocating a bay of an intelligent cabinet according to any one of claims 1 to 10 when executing the computer program.