CN111784469B

CN111784469B - Order sub-broadcasting rechecking method, device, equipment and storage medium

Info

Publication number: CN111784469B
Application number: CN202010629624.5A
Authority: CN
Inventors: 许群合
Original assignee: Beijing Jingdong Zhenshi Information Technology Co Ltd
Current assignee: Beijing Jingdong Zhenshi Information Technology Co Ltd
Priority date: 2020-06-29
Filing date: 2020-06-29
Publication date: 2024-04-09
Anticipated expiration: 2040-06-29
Also published as: CN111784469A

Abstract

The application discloses a method, a device, equipment and a storage medium for order multicast review, which specifically comprise the following steps: acquiring an order set corresponding to a current picking container for loading commodities from an order database; determining the type of the multicast wall for receiving the multicast review according to the number of the orders and the calculated average commodity number of the orders; determining binding relations among grid openings distributed for each order number; and running a corresponding sub-broadcasting rechecking process according to the type of the sub-broadcasting wall, obtaining the sub-broadcasting information of each order generated after sub-broadcasting rechecking, and storing the sub-broadcasting information of each order in the order database. By applying the scheme of the embodiment of the application, the system processing center can intelligently select the proper sub-broadcasting wall for the sub-broadcasting re-checking work according to the actual condition of the order, the order sub-broadcasting re-checking work can be better met, the on-site resources are reasonably distributed, and the complex operation and error rate of staff are reduced.

Description

Order sub-broadcasting rechecking method, device, equipment and storage medium

Technical Field

The present disclosure relates to the field of computer technologies, and in particular, to an order distribution review method, an order distribution review device, a computer readable storage medium, and an electronic apparatus.

Background

With the rise of electronic commerce, more and more users shop through an online shopping platform. In the online shopping process, the online shopping platform generates a trade order for the user according to the trade condition of the user. The online shopping platform then sorts the goods according to the order content, packages the goods, and sends the packaged goods to the user through the distribution system. Because of the large number of users for online shopping, each order may contain multiple items, and the same item may be purchased by multiple different users, which is very complex. In order to ensure that each user is shipped correctly, the online shopping platform can also perform sub-broadcasting rechecking on the order after picking, and package the goods to continue the next link after the goods in the order are completely corresponding to the sorted goods.

In the existing order review scheme, workers usually place the centrally sorted commodities one by one in a turnover basket of a distribution wall according to system instructions to achieve review. However, as mentioned above, the actual order situation is very complex and a single system indication does not meet the demand well or arrange the resources reasonably. For example, the number of orders to be checked is relatively large, or the number of commodities in each order is relatively large, if the orders cannot be reasonably arranged, the existing system may not fully utilize the distribution wall, or the operation of staff is excessively complicated, so that the working strength and the error rate of checking the orders are increased.

Disclosure of Invention

Aiming at the prior art, the embodiment of the application discloses an order rechecking method, which can avoid unreasonable defects of on-site resource allocation, and achieves the purposes of reasonably allocating resources and reducing the working strength and the error rate.

Based on this, the order distribution review method provided in the embodiment of the present application includes:

acquiring an order set corresponding to a current picking container for loading commodities from an order database, wherein the order set at least comprises order numbers and orders, and each order at least comprises an order number, a commodity identification code and a commodity number;

determining the type of the multicast wall for receiving the multicast review according to the number of the orders and the calculated average commodity number of the orders;

determining binding relations among grid openings distributed for each order number;

and running a corresponding sub-broadcasting rechecking process according to the type of the sub-broadcasting wall to obtain sub-broadcasting information of each order generated after sub-broadcasting rechecking, wherein each piece of sub-broadcasting information of each order comprises an order number, a commodity identification code and the commodity quantity, and storing the sub-broadcasting information of each order in the order database.

Further, the method comprises the steps of,

the branch for receiving the branch check is determined according to the number of orders and the calculated average commodity number of the orders

The wall sowing type comprises the following steps:

if the number of orders is smaller than or equal to a preset first threshold value and the average commodity number of the orders is smaller than or equal to a preset second threshold value, determining that the type of the sub-broadcasting wall receiving sub-broadcasting review is a small vertical sub-broadcasting wall;

if the number of orders is larger than a preset first threshold value and the average commodity number of the orders is smaller than or equal to a preset second threshold value, determining that the type of the multicast wall for receiving the multicast review is a large vertical multicast wall;

and if the average commodity number of the order is larger than a preset second threshold value, determining that the type of the multicast wall for receiving the multicast review is a horizontal multicast wall.

Further, the method comprises the steps of,

the step of running the corresponding sub-cast rechecking process according to the type of the sub-cast wall comprises the following steps:

if the type of the sub-broadcasting wall for receiving sub-broadcasting rechecking is a small vertical sub-broadcasting wall, running a sub-broadcasting rechecking process according to commodities;

if the type of the sub-broadcasting wall for receiving sub-broadcasting rechecking is a large vertical sub-broadcasting wall, running a sub-broadcasting rechecking process according to commodities;

and if the type of the multicast wall for receiving the multicast recheck is a horizontal multicast wall, running the multicast recheck process according to the grid openings.

Further, the method comprises the steps of,

the sub-broadcasting rechecking process according to the commodity comprises the following steps:

acquiring a commodity identification code of a current commodity, wherein the current commodity is one commodity loaded in the current commodity picking container;

determining an order number of an order to which the current commodity belongs and a corresponding actual grid according to the commodity identification code, displaying each virtual grid corresponding to the order number to which the current commodity belongs in a set virtual distribution wall, and displaying the commodity identification code of the current commodity and the commodity number of the current commodity in each virtual grid;

acquiring grid port distribution completion information aiming at the current commodity, wherein the grid port distribution completion information represents information of placing the current commodity in a turnover container corresponding to a grid port according to the commodity number of the current commodity displayed in the virtual grid port;

subtracting the commodity number of the current commodity from the order set, and adding the commodity number of the current commodity to the set order distribution information;

and returning to the step of acquiring the commodity identification code of the current commodity until all the commodities loaded in the current commodity sorting container are processed.

Further, the method comprises the steps of,

The multicast rechecking process according to the grid port comprises the following steps:

acquiring a grid port identification code of a current grid port, wherein the current grid port is one grid port of an actual distribution wall corresponding to the distribution wall type;

determining an order number corresponding to the current grid according to the grid identification code, determining all commodity identification codes and commodity quantity corresponding to the order number, displaying a virtual grid corresponding to the current grid in a set virtual multicast wall, and displaying all commodity identification codes and commodity quantity in the corresponding order in the virtual grid;

acquiring a commodity identification code of a current commodity, wherein the current commodity is one commodity which is loaded by the current goods-picking container and belongs to the current grid;

returning the next commodity belonging to the current grid as the current commodity to the step of acquiring the commodity identification code of the current commodity until all the commodities belonging to the current grid are processed;

acquiring grid port distribution completion information aiming at the current grid port, wherein the grid port distribution completion information represents information that all commodities in the corresponding order are placed in a turnover container of the corresponding grid port according to commodity identification codes and commodity quantity displayed in the virtual grid port;

And returning the next grid as the current grid to the step of acquiring the grid identification code of the current grid until all the commodities loaded in the current goods-picking container are processed.

Further, the method comprises the steps of,

the step of determining the binding relation among the order numbers, the lattice ports allocated to the orders and the turnover containers further comprises the steps of binding the order numbers with the allocated turnover containers, wherein the step of determining the binding relation among the order numbers, the lattice ports allocated to the orders and the turnover containers comprises the following steps:

firstly, distributing actual grid openings for each order according to the acquired order set corresponding to the current picking container;

and sequentially acquiring a grid identification code of an actual grid and a container identification code of an allocated actual turnover container, binding the order number corresponding to the actual grid, the grid and the allocated turnover container, and returning to the execution of the step until all the binding of the order number, the grid and the turnover container is completed.

The embodiment of the application also discloses an order rechecking device which can avoid unreasonable defects of on-site resource allocation, and achieves the purposes of reasonably allocating resources and reducing the working strength and the error rate.

Based on this, an order-distribution review device provided in the embodiment of the present application includes:

The database operation module is used for acquiring an order set corresponding to a current picking container for loading commodities from an order database, wherein the order set at least comprises order numbers and orders, and each order at least comprises an order number, a commodity identification code and a commodity number; storing the order distribution information in the order database;

the type determining module is used for determining the type of the multicast wall for accepting the multicast review according to the number of the orders and the calculated average commodity number of the orders;

the binding module is used for determining binding relations between each order number and the grid openings distributed for each order;

and the sub-broadcasting re-checking execution module is used for running a corresponding sub-broadcasting re-checking process according to the type of the sub-broadcasting wall to obtain the sub-broadcasting information of each order generated after sub-broadcasting re-checking, wherein each order sub-broadcasting information comprises the order number, the commodity identification code and the commodity quantity.

Further, the method comprises the steps of,

the multicast rechecking execution module comprises:

the sub-broadcasting rechecking module is used for acquiring the commodity identification code of the current commodity, wherein the current commodity is one commodity loaded in the current commodity sorting container; determining an order number of an order to which the current commodity belongs and a corresponding actual grid according to the commodity identification code, displaying each virtual grid corresponding to the order number to which the current commodity belongs in a set virtual distribution wall, and displaying the commodity identification code of the current commodity and the commodity number of the current commodity in each virtual grid; acquiring grid port distribution completion information aiming at the current commodity, wherein the grid port distribution completion information represents information of placing the current commodity in a turnover container corresponding to a grid port according to the commodity number of the current commodity displayed in the virtual grid port; subtracting the commodity number of the current commodity from the order set, and adding the commodity number of the current commodity to the set order distribution information; returning to the step of acquiring the commodity identification code of the current commodity until all the commodities loaded in the current commodity sorting container are processed;

The grid-based sub-broadcasting rechecking module is used for acquiring a grid identification code of a current grid, wherein the current grid is one of the grid of the actual sub-broadcasting wall corresponding to the type of the sub-broadcasting wall; determining an order number corresponding to the current grid according to the grid identification code, determining all commodity identification codes and commodity quantity corresponding to the order number, displaying a virtual grid corresponding to the current grid in a set virtual multicast wall, and displaying all commodity identification codes and commodity quantity in the corresponding order in the virtual grid; acquiring a commodity identification code of a current commodity, wherein the current commodity is one commodity which is loaded by the current goods-picking container and belongs to the current grid; subtracting the commodity number of the current commodity from the order set, and adding the commodity number of the current commodity to the set order distribution information; returning the next commodity belonging to the current grid as the current commodity to the step of acquiring the commodity identification code of the current commodity until all the commodities belonging to the current grid are processed; acquiring grid port distribution completion information aiming at the current grid port, wherein the grid port distribution completion information represents information that all commodities in the corresponding order are placed in a turnover container of the corresponding grid port according to commodity identification codes and commodity quantity displayed in the virtual grid port; and returning the next grid as the current grid to the step of acquiring the grid identification code of the current grid until all the commodities loaded in the current goods-picking container are processed.

The embodiment of the application also provides a computer readable storage medium, on which computer instructions are stored, which is characterized in that the order distribution review method can be realized when the instructions are executed by a processor.

The embodiment of the application also provides electronic equipment, which at least comprises the computer readable storage medium and a processor;

the processor is configured to read the executable instructions from the computer-readable storage medium and execute the instructions to implement the order distribution review method described above.

In summary, in the embodiment of the present application, instead of randomly allocating on-site multicast wall resources, the type of the multicast wall receiving the multicast review is determined according to the actual situation of the order, and a corresponding multicast review process is operated according to the type of the multicast wall. Therefore, the scheme of the embodiment of the application can intelligently select the proper sub-broadcasting wall for the sub-broadcasting re-checking work, better meet the order sub-broadcasting re-checking work, reasonably allocate the field resources and reduce the complexity and error rate of the operation of staff.

Drawings

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

Fig. 1 is a schematic diagram of an application scenario one of the embodiments of the present application.

Fig. 2 is a flowchart of a first embodiment of a method for implementing order distribution review in the present application.

Fig. 3 is a schematic diagram of an application scenario two according to an embodiment of the present application.

Fig. 4 is a flowchart of a second embodiment of a method for implementing order distribution review in the present application.

Fig. 5 is a flowchart of a multicast review process per commodity according to an embodiment of the present application.

Fig. 6 shows the effect of the system in the process of checking by the sub-broadcasting of the commodity.

Fig. 7 is a flowchart of a multicast review process implemented per-bin according to an embodiment of the present application.

Fig. 8 shows the effect of the system in the check-in-drop process according to the grid.

Fig. 9 is a block diagram of an embodiment one of an order-distribution review device implemented in the present application.

Fig. 10 is a block diagram of another embodiment of an order distribution review device implemented in the present application.

Fig. 11 is a schematic structural diagram of an electronic device according to an embodiment of the present application.

Detailed Description

The following description of the technical solutions in the embodiments of the present application will be made clearly and completely with reference to the drawings in the embodiments of the present application, and it is apparent that the described embodiments are only some embodiments of the present application, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art without undue burden from the present disclosure, are within the scope of the present disclosure.

The terms "first," "second," "third," "fourth" and the like in the description and in the claims and in the above drawings, if any, are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that the embodiments of the invention described herein may be implemented, for example, in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprise" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those elements but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

The technical scheme of the invention is described in detail below by specific examples. The following embodiments may be combined with each other, and some embodiments may not be repeated for the same or similar concepts or processes.

In the embodiment of the application, the multicast walls are divided into different types, and each type of the multicast wall corresponds to a respective multicast rechecking process, and the specific multicast rechecking processes can be the same or different. When an order set needing to be subjected to the sub-broadcasting review is acquired, which type of sub-broadcasting wall is suitable for carrying the sub-broadcasting review according to the information in the order set can be judged, then a corresponding sub-broadcasting review process is operated, a plurality of order sub-broadcasting information is acquired, and finally the order sub-broadcasting review is completed. The following detailed description is provided for better explaining the embodiments of the present application.

Fig. 1 is a schematic diagram of an application scenario one of the embodiments of the present application. As shown in fig. 1, a site where a multicast review is performed typically includes a system processing center and several different types of multicast walls. As described above, the online shopping platform performs the multicast review after the order picking is completed. The staff first picks up the goods in the orders into a pick container (such as a pick cart), and the order database of the system processing center records the order. The picking process is not an important aspect of the present application and will not be described in detail herein. After the picking is finished, the system instructs the sub-sowing to recheck, and the staff places the commodity in the sub-sowing wall according to the system instruction so as to verify whether the actual commodity is consistent with the commodity of the order or not and whether the actual commodity is completely accurate or not. After the sub-broadcasting review is completed, the commodities of each order are packaged respectively, and the next step such as a distribution link is performed.

A distribution wall is a device for carrying commodities, and generally comprises a plurality of grid openings, wherein orders and the grid openings are arranged in a binding relationship. Further, a turnover container can be placed in the portal, placing the order, the portal, and the turnover container in a binding relationship. Then, the staff distributes the goods in the goods-picking container into the corresponding grid or turnover container one by one, and checks whether the goods-picking result is matched with the order, thereby achieving the aim of distributing and checking. Because of the large order volume and the large number of goods, each operation step of the distribution is usually automatically indicated by the system in order to avoid manual errors as much as possible. In order to distinguish between actual equipment in a distribution site and virtual equipment in a system, in the embodiments of the present application, a distribution wall displayed in the system is referred to as a "virtual distribution wall", and a grid displayed in the system is referred to as a "virtual grid".

In addition, the types of the unicast walls illustrated in the scenario of fig. 1 may include a small vertical unicast wall, a large vertical unicast wall, and a horizontal unicast wall. The small vertical type separating wall is a separating wall with relatively few layers and relatively few grid openings of each layer. In addition, such a wall is generally stacked in a three-dimensional manner, so that this embodiment is called a small vertical wall. The large vertical type dividing wall is a dividing wall with relatively more layers and relatively more grid openings of each layer. Such a wall is also commonly stacked in a three-dimensional manner, and thus this embodiment is referred to as a large vertical wall. Horizontal multicast walls refer to relatively large openings, typically horizontally disposed (e.g., on the ground), and are therefore referred to as horizontal multicast walls. Of course, other types of distributing walls are available in practice, and are not fully illustrated in fig. 1.

Fig. 2 is a flowchart of a first embodiment of a method for implementing order distribution review in the present application. As shown in fig. 2, the method includes:

step E1: and acquiring an order set corresponding to the current picking container for loading the commodities from an order database, wherein the order set at least comprises order numbers and orders, and each order comprises an order number, a commodity identification code and a commodity number.

As previously described, in order picking, the order database records which orders the current picking container loads correspond to, i.e., the set of orders that make up, in order picking the picking container to complete the picking. Thus, the system processing center may obtain the order set corresponding to the current pick container from the order database.

Step E2: and determining the type of the multicast wall for receiving the multicast review according to the order quantity and the calculated average commodity quantity of the order.

In order to better meet the requirement of the multicast rechecking, the resources are more reasonably allocated. In the embodiment of the application, instead of randomly designating a multicast wall from the site for carrying out multicast review, the type of the multicast wall is intelligently determined according to the information in the order set corresponding to the current picking container, and a worker can select an appropriate multicast wall from the site according to the type of the multicast wall determined by the system. As can be seen from the description of the above-mentioned multicast wall, different types of multicast walls have different characteristics. In the order set obtained by the system, the order quantity is used for indicating how many dividing walls of the grid are needed, the average commodity quantity of the order indicates how large dividing walls of the grid are needed, and the type of the dividing walls can be determined through two parameters, namely the order quantity and the average commodity quantity of the order.

Step E3: and determining binding relations among the order numbers and the grid openings allocated for the orders.

In practical application, the turnover container can be further placed in the grid, so that binding relation among each order number, the grid and the turnover container is needed to be determined, wherein the grid is the grid of the practical distribution wall corresponding to the distribution wall type, and the turnover container is a container placed in the grid and used for bearing commodities; each of the lattice openings corresponds to a lattice opening identification code, and each of the turnover containers corresponds to a container identification code.

After the staff chooses the proper distributing wall from the site according to the system prompt, the current picking container can be moved to the vicinity of the chosen actual distributing wall to implement the distributing review work of the order. It is contemplated that, due to the relatively large physical space of the site, in addition to the selected wall, a workstation of the system processing center may be located in the vicinity thereof to perform the functions of the system processing center for ease of operation. In practice, the workstation of the system processing center is colloquially referred to as a "review station" or "host computer", or the like. Regardless of what is actually called, the operator can be instructed to perform the multicast review operation. Fig. 3 is a schematic diagram of an application scenario two in the embodiment of the present application. As shown in fig. 3, the scenario includes a distribution wall 31, a system processing center workstation 32, and a pick container 33. In addition, an identification code reader 34 is also required for subsequent acquisition of various identification codes. In this scenario, to not confuse the items in the order, the order number needs to be bound to the slot assigned to the order first. Since multiple orders are included in the order set, there should also be multiple such binding relationships. In practical application, binding can be realized in various modes between the order number and the grid. For example, the system processing center has recorded the order number of the order, and the site identifier reader 34 may be used to read the corresponding port identifier (not shown in the figure) into the system processing center, so as to bind the order number and the port. Further, if a turnover container is placed in the grid, a container identification code (not shown in the figure) corresponding to the actual turnover container needs to be read into a system processing center workstation by using an on-site identification code reader 34, so that the order number, the grid and the turnover container are bound.

Step E4: and running a corresponding sub-broadcasting rechecking process according to the type of the sub-broadcasting wall to obtain sub-broadcasting information of each order generated after sub-broadcasting rechecking, wherein each order sub-broadcasting information comprises the order number, the commodity identification code and the commodity quantity, and storing each order sub-broadcasting information in the order database.

As previously described, each different type of multicast wall corresponds to a respective multicast review process. In the process of the sub-broadcasting and rechecking, on-site staff can take out the commodity from the picking container and place the commodity in a grid corresponding to the order number according to the prompt of the system. Accordingly, the system processing center workstation may generate a number of order distribution information. The order distribution information comprises order numbers, commodity identification codes and commodity quantity so as to indicate which grid port the commodity in a certain order is placed in, thereby completing the distribution of the commodity and further facilitating the check of whether the commodity is consistent with the order requirement. Similarly, if the turnover container is placed in the grid, the on-site staff can take out the commodity from the picking container according to the prompt of the system and place the commodity in the turnover container corresponding to the grid of the order number, and the order distribution information also further comprises the container identification code of the turnover container.

By applying the scheme of the embodiment of the application, the system processing center can intelligently select the proper sub-broadcasting wall for the sub-broadcasting re-checking work according to the actual condition of the order, the order sub-broadcasting re-checking work can be better met, the on-site resources are reasonably distributed, and the complex operation and error rate of staff are reduced.

In order to better illustrate the present application, another embodiment is described in detail below. Fig. 4 is a flowchart of a second embodiment of a method for implementing order distribution review in the system processing center of the present application. The implementation scenes of steps F1 to F4 are shown in fig. 1, and the implementation scenes of steps F5 to F10 are shown in fig. 3. As shown in fig. 4, the method embodiment of the present application includes:

step F1: and acquiring an order set corresponding to the current picking container for loading the commodities from an order database, wherein the order set at least comprises order numbers and orders, and each order comprises an order number, a commodity identification code and a commodity number.

This step is the same as step E1 of method embodiment one.

Step F2: and if the number of orders is smaller than or equal to a preset first threshold value and the average commodity number of the orders is smaller than or equal to a preset second threshold value, determining that the type of the multicast wall for receiving the multicast review is a small vertical multicast wall, and jumping to the step F5.

Step F3: and if the number of orders is larger than a preset first threshold value and the average commodity number of the orders is smaller than or equal to a preset second threshold value, determining that the type of the multicast wall for receiving the multicast review is a large vertical multicast wall, and jumping to the step F5.

Step F4: and if the average commodity number of the order is greater than a preset second threshold, determining that the type of the multicast wall for receiving the multicast review is a horizontal multicast wall, and jumping to the step F5.

The steps F2 to F4 are specific methods for determining the type of the multicast wall, that is, specific implementation of step E2 in the method embodiment. In this embodiment, a first threshold is set for the number of orders, a second threshold is set for the average number of commodities in the order, and the type of the distribution wall is determined according to the two thresholds and the actual situation of the order. Such as: the first threshold is set to 100 and the second threshold is set to 20. The number of orders in a certain order set is 20, and the average commodity number of orders is 3, so that the situation that the order set belongs to fewer orders and fewer commodities are required in each order can be judged, the small vertical type of the sub-sowing wall is enough to meet the requirement of sub-sowing re-checking, and the type of the sub-sowing wall for receiving the sub-sowing re-checking can be determined to be the small vertical type of the sub-sowing wall. The number of orders in the other order set is 60, but the average commodity number of the orders is 50, so that the situation that the number of commodities in the order set is relatively large can be judged, and the requirement of the horizontal type distribution wall for distribution review can be better met.

Step F5: and distributing a grid for each order according to the acquired order set corresponding to the current picking container.

In practical application, after determining the type of the distributing wall in step F4, the staff member may move the current pick-up container loaded with the commodity to the vicinity of the actual distributing wall conforming to the determined type of the distributing wall, i.e. enter the second scene. A system processing center is also provided in this scenario, or a system processing center workstation 32 that is part of the system processing center, may have previously acquired the set of orders corresponding to the current pick container. Of course, in the actual application, in the case of the second scenario, the pick-up container identifier corresponding to the current pick-up container may be read again into the system processing center workstation 32 by the configured identifier reader 34, and the corresponding order set may be acquired according to the pick-up container identifier. The pick-up container identification code described herein may be a bar code, a two-dimensional code, an electronic tag, an ID card, etc., and the identification code reader 34 may be a scanning gun, an RFID reader, an RFID ID reader, etc.

Because the order collection comprises order data, information such as each order and the like, the system processing center can easily allocate an actual format for each order.

For example, a certain order is assembled with 10 orders, the order numbers are D01-D10, and the format of each order is shown in the following table:

list one

Assuming that the distributed actual distribution wall has 15 grids, orders D01 to D10 can be directly distributed to 10 grids respectively. In practical applications, step F5 may be referred to as a "binding" process, i.e. establishing a binding relationship between the order and the grid.

Step F6: and acquiring a grid port identification code of a grid port and a container identification code of the distributed turnover container, and binding the corresponding order number, the grid port and the turnover container.

After the actual lattice openings are allocated for the orders, an actual turnover container is placed on the corresponding lattice opening and used for carrying the goods which are subsequently taken out from the current picking container by staff. In order to distinguish which order the goods of the turnover container belong to, the grid and the turnover container need to be further bound. Because each grid corresponds to a grid identification code, each turnover container corresponds to a container identification code. The lattice openings are lattice openings in the site distribution wall, and the turnover containers are physical turnover containers placed in the lattice openings in site. For binding, the identification code reader 34 may be used to read the format identification code and the container identification code in sequence in practical application, to indicate the binding relationship established by the format identification code and the container identification code. Similarly, the bin and container identification codes may be bar codes, two-dimensional codes, electronic tags, ID cards, etc., and the identification code reader 34 may be a scanning gun, RFID reader, RFID ID reader, etc. In practical applications, step F6 may also be referred to as a "binding container" process, i.e. establishing a binding relationship between the portal and the turnover container.

At this time, since the step F5 establishes a binding relationship between the order and the portal, the step F6 establishes a binding relationship between the portal and the turnover container, and thus also establishes a binding relationship between the order, the portal and the turnover container. Still taking the above listed order set as an example, the binding relationship is specifically shown in table two:

order number	Grating identification code	Identification code for turnover container
			D01	G01	R01
D02	G02	R02
			…	…	…
D10	G10	R10

Watch II

Step F7: f8, judging whether binding of all order numbers, grid ports and turnover containers is finished, if yes, continuing to carry out the step F8; otherwise, return to step F6.

If a plurality of orders exist, the steps F6 to F7 are circulated for a plurality of times, and all the binding is completed. At this point, the system processing center has bound the orders, assigned bins, assigned turnover containers that are currently involved in the pick container, and the following multicast review process can take place.

Step F8: if the type of the sub-broadcasting wall receiving sub-broadcasting rechecking is a small vertical sub-broadcasting wall, running a sub-broadcasting rechecking process according to commodities to obtain sub-broadcasting information of each order generated after sub-broadcasting rechecking, wherein each order sub-broadcasting information comprises the container identification code, the order number, the commodity identification code and the commodity number, storing the sub-broadcasting information of each order in the order database, and ending the flow.

Step F9: and if the type of the sub-broadcasting wall for receiving sub-broadcasting re-checking is a large vertical sub-broadcasting wall, running a sub-broadcasting re-checking process according to commodities to obtain the sub-broadcasting information of each order generated after sub-broadcasting re-checking, wherein each piece of sub-broadcasting information of each order comprises the container identification code, the order number, the commodity identification code and the commodity number, and storing the sub-broadcasting information of each order in the order database.

Step F10: if the type of the multicast wall for receiving the multicast review is a horizontal multicast wall, running a multicast review process according to a grid port to obtain each order multicast information generated after the multicast review, wherein each order multicast information comprises the container identification code, the order number, the commodity identification code and the commodity number, storing each order multicast information in the order database, and ending the flow.

The steps F8 to F10 are different multicast rechecking processes for three types of multicast walls. The staff can place the commodity one by one in the actual turnover container according to the information of system prompt, accomplish the branch sowing of commodity. The embodiment of the application provides a sub-broadcasting and rechecking process according to commodities and a sub-broadcasting and rechecking process according to grid openings, and the specific flow can be seen in the following embodiment. However, in either of the sub-broadcasting review processes, the order sub-broadcasting information is generated after sub-broadcasting and stored in the order database.

Different multicast walls have different characteristics and accord with different order situations. The embodiment of the application provides a sub-broadcasting rechecking process according to commodities, which specifically describes how to realize sub-broadcasting rechecking according to different commodities. In the process of checking and rechecking according to commodities, the commodities are mainly used for implementing the multicasting. Fig. 5 is a flowchart of a multicast review process per commodity according to an embodiment of the present application. As shown in fig. 5, the method includes:

step M1: and acquiring a commodity identification code of the current commodity, wherein the current commodity is one commodity loaded in the current commodity picking container.

In practical application, staff can randomly take out a commodity from the current goods picking container to carry out code scanning identification. Each item is attached with an item identification code, such as an item SUK bar code, which may be read by a scanning gun as an identification code reader 34 and transmitted to a system processing center. By the method, the system processing center can acquire the commodity identification code of the current commodity.

Step M2: determining an order number of an order to which the current commodity belongs and a corresponding grid according to the commodity identification code, displaying each virtual grid corresponding to the order number to which the current commodity belongs in a set virtual distribution wall, and displaying the commodity identification code of the current commodity and the commodity number of the current commodity in each virtual grid.

In order to facilitate the operation of the staff, the system processing center may set a virtual multicast wall corresponding to the assigned multicast wall, and embody the binding relationship between the order number and the grid. For example, the system processing center receives the uploaded product identifier S02, and supposing that the product identifier S02 corresponds to the product "vinegar", and the product belongs to three orders D01, D06 and D07, wherein 2 products are required for the D01 order, 3 products are required for the D06 order, and 1 product is required for the D07 order. The system processing center may then show the demand in the workstation's display screen. Fig. 6 shows the effect of the system in the process of checking by the sub-broadcasting of the commodity. As shown in fig. 6, the vertical virtual wall 61 and a plurality of virtual grids are included, and the layout of the virtual grids is completely consistent with that of the actual grids. According to the above assumption, the virtual ports G01, G06, and G07 may be highlighted (indicated by oblique lines in the drawing), and the commodity number of the commodity corresponding to the commodity identification code S02 is displayed. Furthermore, for convenient reading, commodity names can be displayed in the virtual grid.

At this time, the worker can perform the distribution according to the prompt of the system shown in fig. 6. For example, 2 bottles of vinegar are taken out from the current picking container and placed in an actual turnover container R01 corresponding to an actual grid corresponding to G01, and a scanning gun is used for reading a grid identification code G01 to indicate that the current commodity distribution is completed, and the system continues to execute the step M3. Other cells also use similar methods.

Step M3: and acquiring grid port distribution completion information aiming at the current commodity, wherein the grid port distribution completion information represents information of placing the current commodity in a turnover container corresponding to the grid port according to the commodity number of the current commodity displayed in the virtual grid port.

As described above, after the staff places a certain commodity in the corresponding turnover container according to the system prompt, the scanner gun can be used again to read the gate identification code. At this time, the system processing center acquires the grid identification code and takes the grid identification code as the grid distribution completion information of the current commodity. Of course, the system may also provide that other information is used as the port distribution completion information, for example, the identification code of the scanning container is used as the port distribution completion information, for example, a button is arranged on the scanning gun, and the information generated by pressing the button is used as the port distribution completion information.

Step M4: subtracting the commodity number of the current commodity from the order set, and adding the commodity number of the current commodity to the set order distribution information.

Initially, the system processing center obtains a collection of orders, including a number of orders. In order to check whether the goods obtained by each grid port are consistent with the order, order distribution information can be set. The order distribution information may be as shown in table three:

Watch III

When the order is separated, the corresponding quantity can be subtracted from the original order set (table one), and the corresponding quantity is added to the order separated information (table three) so as to keep consistent with the actual separated process.

The above steps M3 and M4 describe a case where one commodity is placed in the corresponding pocket. If the commodity needs to be placed in a plurality of grids, the steps M3 and M4 can also be circularly executed until the commodity is fully and partially sown to the plurality of grids.

Step M5: judging whether all commodities are processed, and if not, returning to the step M1; otherwise, the process is exited.

If other commodities exist in the current picking container, the staff needs to take out the other commodities again, and repeat the steps M1 to M4 until all the commodities loaded in the current picking container are distributed. At this time, if the operation is correct, the number of all the commodities in the order set should be reduced to 0, and the commodities are reflected in order distribution information. Therefore, a worker can check whether the commodity is completely consistent with the order or not conveniently. Assuming that a certain order set is shown in table four, the commodity identification code S02 corresponds to commodity "vinegar", 2 commodities are required for a D01 order, 3 commodities are required for a D06 order, and 1 commodity is required for a D07 order.

Table four

When the sub-broadcasting rechecking process according to the commodities is executed, the order set is updated to be shown in a table five, and the set order sub-broadcasting information can be shown in tables six to eight:

TABLE five

TABLE six

Watch seven

Table eight

As can be seen from the above tables six to eight, the present embodiment divides the original order set into a plurality of order distribution information corresponding to the container identification codes.

The above description describes the case of separately checking one picking container, and if the number of goods in a certain order set is very large, one picking container cannot load all goods, but is loaded in a plurality of picking containers. In this case, the same method may be used to continue dispensing of the goods in the other pick-up containers until completed.

In the embodiment of the application, in the process of checking and sub-broadcasting according to commodities, the system is mainly implemented aiming at the commodities, and the same commodity is sub-broadcast into actual turnover containers corresponding to different orders. Because the number of layers of the small vertical type separate sowing wall is smaller, each layer of lattice opening is smaller, even if the same commodity needs to be separated into the turnover containers with different lattice openings, workers can move in a relatively smaller space, and the large physical waste can not be caused. Therefore, aiming at the conditions of small orders and small average commodity quantity in the orders, the small vertical type sub-sowing wall is adopted to receive sub-sowing re-checking work and is implemented according to the sub-sowing re-checking process of the commodity, so that the method is a comparatively optimized scheme.

In practical application, aiming at the situation that the number of orders is large, but the average commodity number in the orders is small, a large vertical type separate sowing wall can be adopted to receive separate sowing and rechecking work. Although the large vertical type sub-broadcasting wall may have more grid openings of each layer, the activity space of the staff is not too large, and the method can be implemented according to the sub-broadcasting rechecking process of the commodity, and is also a comparatively optimized scheme.

The embodiment of the application also provides a multicast rechecking process according to the grid, and particularly introduces how to realize the multicast rechecking according to the different grid. In the multicast rechecking process according to the lattice, the lattice is used as the main material to implement the multicast. Fig. 7 is a flowchart of a multicast review process implemented per-bin according to an embodiment of the present application. As shown in fig. 7, the method includes:

step N1: and acquiring a grid port identification code of a current grid port, wherein the current grid port is one grid port of the multicast wall corresponding to the type of the multicast wall.

Unlike the previous embodiment, the present embodiment does not acquire the article identification code first, but acquires the cell identification code of the current cell. In some large orders, each order contains a relatively large number of items that need to be placed in a horizontal distribution wall with a relatively large grid. The horizontal type dividing wall is generally provided with the grid openings on the ground, the distance between the grid openings is original, and the overall occupied area is large. If the method is still implemented according to the commodity-based sub-broadcasting rechecking process, the sub-broadcasting task can be completed, but workers need to go back and forth for many times between oversized grids, so that the complexity of work is increased. Therefore, in this embodiment, the multicast is first performed on the cell, and the cell identifier of the current cell is first obtained.

Step N2: determining an order number corresponding to the current grid according to the grid identification code, determining all commodity identification codes and commodity quantity corresponding to the order number, displaying a virtual grid corresponding to the current grid in a set virtual multicast wall, and displaying all commodity identification codes and commodity quantity in the corresponding order in the virtual grid.

This step is similar to step M2 of the above embodiment, except that all the product identifiers and the product numbers of the current grid are required to be displayed. Assume that the system processing center receives an uploaded port identification code G01, which indicates that a multicast is currently required for the G01 port. Assuming that the order corresponding to the lattice identification code includes 25 commodities, the commodity identification code, commodity name and commodity number are respectively: (S01, pillowcase, 2), (S02, towel, 2) … …), the system processing center may display this information on the display screen during operation. Fig. 8 shows the effect of the system in the check-in-drop process according to the grid. As shown in fig. 8, the horizontal virtual wall 81 is included, and a plurality of virtual ports are formed, and the layout of the virtual ports is completely identical to that of the actual ports. According to the above assumption, the corresponding virtual cell G01 is highlighted (indicated by diagonal lines in the figure), and the commodity corresponding to the commodity identification codes S01 to S25 is displayed.

Step N3: and acquiring a commodity identification code of the current commodity, wherein the current commodity is one commodity which is loaded by the current goods-picking container and belongs to the current grid.

At this time, the worker can perform the distribution according to the prompt of the system shown in fig. 8. For example, 2 pillowcases are taken out from the current picking container and placed in the actual turnover container R01 corresponding to the G01 grid. Then, the staff can read the grid identification code G01 by using the scanning gun to indicate that the current commodity distribution is completed, and the system continues to execute the step M3. Other cells also use similar methods.

Step N4: subtracting the commodity number of the current commodity from the order set, and adding the commodity number of the current commodity to the set order distribution information.

This step is the same as step M4 of the above embodiment.

Step N5: judging whether all commodities of the current grid are processed, if so, continuing to execute the step N7; otherwise, step N6 is performed.

Step N6: and (3) taking the next commodity belonging to the current grid as the current commodity, and returning to the step (N3).

The steps N3 to N6 are a circulation process, and the goods belonging to the bin G01 are continuously taken out from the current picking container and placed in the corresponding actual turnover container. For example, 2 pillowcases are taken out in the first cycle, 2 towels are taken out in the second cycle, and so on until all goods of the grid G01 are placed in the corresponding actual turnover container.

Step N7: and acquiring the grid port distribution completion information aiming at the current grid port, wherein the grid port distribution completion information represents information of placing all the commodities in the corresponding order in a turnover container of the corresponding grid port according to the commodity identification codes and the commodity quantity displayed in the virtual grid port.

This step is the same as step M3 in the above embodiment.

In this embodiment, the order set and the order distribution information are updated in the step N4, and in practical application, the method may also be executed after the step N7, and information similar to table three is obtained as long as the information can be recorded in time and kept consistent with the actual distribution process.

Step N8: judging whether all commodities are processed, and ending the flow if the commodities are processed; otherwise, step N9 is performed.

To this end, all the goods belonging to the grid G01 have been placed in the corresponding actual turnover container. Accordingly, the system processing center has deleted the relevant merchandise information from the order set and added it to the order distribution information.

Step N9: and taking the next grid as the current grid, and returning to the step N1.

If a plurality of orders exist, the staff member moves to the next actual grid, and repeatedly executes the steps of N1-N9 for the next grid, thereby completing the sub-sowing review of all orders related to the current picking container.

It can be seen that in the process of checking the goods according to the grid, the system is mainly implemented for the grid, and the goods of the same grid are intensively distributed into the grid. Under the condition of a large number of commodities in an order, a horizontal type distribution wall with a relatively large grid is required to receive the distribution rechecking work. However, because the grid openings of the horizontal type distributing wall are large, the occupied area is large, and if the distributing wall is still used for distributing commodities, workers can go back and forth for many times in a long distance, so that the work task becomes complicated. According to the embodiment, the sub-broadcasting is carried out according to the grids, and after each grid obtains all corresponding commodities, the commodities are moved to the next grid without long-distance round trip for many times. Assuming that there are X orders, each order requires Y items, in extreme cases, the staff has to move X Y bins. If the method of checking according to the grid openings in the embodiment is adopted, only N grid openings are required to be moved, so that the working efficiency of checking according to the grid openings is greatly improved.

The application also provides an order distribution device which can be implemented in a system processing center or a workstation thereof. Fig. 9 is a block diagram of an embodiment one of an order-distribution review device implemented in the present application. As shown in fig. 9, the apparatus includes: database operation module 91, type determination module 92, binding module 93, and multicast review execution module. Wherein:

The database operation module 91 is configured to obtain, from an order database, an order set corresponding to a current pick-up container for loading the commodity, where the order set includes at least an order number and each order, and each order includes at least an order number, a commodity identification code, and a commodity number; and storing the order distribution information in the order database.

And the type determining module 92 is used for determining the type of the multicast wall for accepting the multicast review according to the number of orders and the calculated average commodity number of the orders.

A binding module 93, configured to determine binding relationships between each order number and the lattice allocated for each order.

The sub-broadcasting re-checking execution module 94 is configured to run a corresponding sub-broadcasting re-checking process according to the type of the sub-broadcasting wall, and obtain the sub-broadcasting information of each order generated after sub-broadcasting re-checking, where each order sub-broadcasting information includes the order number, the commodity identification code and the commodity number.

That is, the database operation module 91 obtains an order set corresponding to the current pick container for loading the goods from the order database; the type determining module 92 determines the type of the multicast wall for receiving the multicast review according to the number of orders and the calculated average commodity number of the orders; the binding module 93 determines binding relations between the order numbers and the lattice openings allocated for the orders; the sub-broadcasting re-checking execution module 94 runs the corresponding sub-broadcasting re-checking process according to the type of the sub-broadcasting wall to obtain the sub-broadcasting information of each order generated after sub-broadcasting re-checking; the order distribution information is stored in the order database by a database operation module 91.

By applying the scheme of the embodiment of the application, the order review device can intelligently select a proper sub-broadcasting wall for sub-broadcasting review work according to the actual condition of the order, can better meet the requirement of the order sub-broadcasting review work, reasonably distributes field resources and reduces the complexity and error rate of the operation of staff.

In another apparatus embodiment, the type determining module 92 may be further specifically configured to, when determining the type of the multicast wall:

In another device embodiment, when the multicast review execution module 94 runs the corresponding multicast review process according to the type of the multicast wall, the multicast review execution module may be further configured to:

In another apparatus embodiment, the binding module 93, when determining the binding relationship between each order number, the actual portal assigned for each order, and the assigned actual turnaround container, may be further configured to:

and sequentially acquiring a grid identification code of an actual grid and a container identification code of an allocated actual turnover container, binding the order number corresponding to the actual grid, the actual grid and the allocated actual turnover container, and returning to the step for execution until all the binding of the order number, the actual grid and the actual turnover container is completed.

In another apparatus embodiment, as shown in fig. 10, the multicast review execution module 94 may include a per-item multicast review module 941 and a per-gate multicast review module 942. Wherein:

The sub-broadcasting rechecking module 941 according to the commodity is used for obtaining the commodity identification code of the current commodity, wherein the current commodity is one commodity loaded in the current commodity picking container; determining an order number of an order to which the current commodity belongs and a corresponding actual grid according to the commodity identification code, displaying each virtual grid corresponding to the order number to which the current commodity belongs in a set virtual distribution wall, and displaying the commodity identification code of the current commodity and the commodity number of the current commodity in each virtual grid; acquiring grid port distribution completion information aiming at the current commodity, wherein the grid port distribution completion information represents information of placing the current commodity in a turnover container corresponding to a grid port according to the commodity number of the current commodity displayed in the virtual grid port; subtracting the commodity number of the current commodity from the order set, and adding the commodity number of the current commodity to the set order distribution information; returning to the step of acquiring the commodity identification code of the current commodity until all the commodities loaded in the current commodity sorting container are processed;

a multicast rechecking module 942 according to the grid openings, configured to obtain a grid opening identification code of a current grid opening, where the current grid opening is one of the grid openings of the actual multicast wall corresponding to the type of the multicast wall; determining an order number corresponding to the current grid according to the grid identification code, determining all commodity identification codes and commodity quantity corresponding to the order number, displaying a virtual grid corresponding to the current grid in a set virtual multicast wall, and displaying all commodity identification codes and commodity quantity in the corresponding order in the virtual grid; acquiring a commodity identification code of a current commodity, wherein the current commodity is one commodity which is loaded by the current goods-picking container and belongs to the current grid; subtracting the commodity number of the current commodity from the order set, and adding the commodity number of the current commodity to the set order distribution information; returning the next commodity belonging to the current grid as the current commodity to the step of acquiring the commodity identification code of the current commodity until all the commodities belonging to the current grid are processed; acquiring grid port distribution completion information aiming at the current grid port, wherein the grid port distribution completion information represents information that all commodities in the corresponding order are placed in a turnover container of the corresponding grid port according to commodity identification codes and commodity quantity displayed in the virtual grid port; and returning the next grid as the current grid to the step of acquiring the grid identification code of the current grid until all the commodities loaded in the current goods-picking container are processed.

According to the embodiment of the application device, the sub-broadcasting review according to the commodity or the sub-broadcasting review according to the grid can be intelligently selected according to the actual order situation. Under the condition that the number of commodities in the order is relatively small, a commodity sub-broadcasting and re-checking process is selected according to the commodities, and workers finish commodity sub-broadcasting in a relatively small space, so that a sub-broadcasting task can be guaranteed, and site resources are saved. Under the condition that the number of commodities in an order is relatively large, a sub-sowing and re-checking process according to the grid is selected, and workers finish sub-sowing of the commodities in a larger space without long-distance round trip, so that a sub-sowing task can be ensured, and the working efficiency is improved.

Embodiments also provide a computer readable storage medium storing instructions that, when executed by a processor, may perform the steps in the order-distribution review method described above. In practice, the computer readable medium may be comprised by or separate from the apparatus/device/system of the above embodiments, and may not be incorporated into the apparatus/device/system. Wherein instructions are stored in a computer readable storage medium which, when executed by a processor, perform the steps in the order-distribution review method described above.

According to embodiments disclosed herein, the computer-readable storage medium may be a non-volatile computer-readable storage medium, which may include, for example, but is not limited to: portable computer diskette, hard disk, random Access Memory (RAM), read-only memory (ROM), erasable programmable read-only memory (EPROM or flash memory), portable compact disc read-only memory (CD-ROM), optical storage device, magnetic storage device, or any suitable combination of the foregoing, but are not intended to limit the scope of the protection herein. In the embodiments disclosed herein, a computer readable storage medium may be any tangible medium that can contain, or store a program for use by or in connection with an instruction execution system, apparatus, or device.

As shown in fig. 11, the embodiment of the application further provides an electronic device. As shown in fig. 1, a schematic structural diagram of an electronic device according to an embodiment of the present invention is shown, specifically:

the electronic device can include a processor 1101 of one or more processing cores, a memory 1102 of one or more computer-readable storage media, and a computer program stored on the memory and executable on the processor. The method of multithreading-based tasks described above may be implemented when the program of the memory 1102 is executed.

Specifically, in practical applications, the electronic device may further include a power supply 1103, an input/output unit 1104, and other components. It will be appreciated by those skilled in the art that the structure of the electronic device shown in fig. 11 is not limiting of the electronic device and may include more or fewer components than shown, or may combine certain components, or a different arrangement of components. Wherein:

the processor 1101 is a control center of the electronic device, connects various parts of the entire electronic device using various interfaces and lines, and performs various functions of a server and processes data by running or executing software programs and/or modules stored in the memory 1102 and calling data stored in the memory 902, thereby performing overall monitoring of the electronic device.

Memory 1102 may be used to store software programs and modules, i.e., the computer-readable storage media described above. The processor 1101 executes various functional applications and data processing by executing software programs and modules stored in the memory 1102. The memory 1102 may mainly include a storage program area and a storage data area, wherein the storage program area may store an operating system, application programs required for at least one function, and the like; the storage data area may store data created according to the use of the server, etc. In addition, memory 1102 may include high-speed random access memory, and may also include non-volatile memory, such as at least one magnetic disk storage device, flash memory device, or other volatile solid-state storage device. Accordingly, the memory 1102 may also include a memory controller to provide the processor 1101 with access to the memory 1102.

The electronic device further includes a power supply 1103 that provides power to the various components and may be logically coupled to the processor 1101 via a power management system, such that the power management system may perform functions such as managing charging, discharging, and power consumption. The power supply 1103 may also include one or more of any of a direct current or alternating current power supply, recharging system, power failure detection circuit, power converter or inverter, power status indicator, etc.

The electronic device may also include an input output unit 1104, which input unit output 1104 may be used to receive input numeric or character information and to generate keyboard, mouse, joystick, optical or trackball signal inputs related to user settings and function control. The input unit output 1104 may also be used to display information entered by a user or provided to a user as well as various graphical user interfaces that may be composed of graphics, text, icons, video, and any combination thereof.

The flowcharts and block diagrams in the figures of the present application illustrate the architecture, functionality, and operation of possible implementations of systems, methods and computer program products according to various embodiments of the present disclosure. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). It should also be noted that, in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams or flowchart illustration, and combinations of blocks in the block diagrams or flowchart illustration, can be implemented by special purpose hardware-based systems which perform the specified functions or acts, or combinations of special purpose hardware and computer instructions.

Those skilled in the art will appreciate that the features recited in the various embodiments of the disclosure and/or the claims may be combined in various combinations and/or combinations, even if such combinations or combinations are not explicitly recited in the present application. In particular, the features recited in the various embodiments and/or claims of the present application may be combined in various combinations and/or combinations without departing from the spirit and teachings of the application, all of which are within the scope of the disclosure.

The principles and embodiments of the present invention have been described herein with reference to specific examples, which are intended to be included herein for purposes of illustration only and not to be limiting of the invention. It will be apparent to those skilled in the art that variations can be made in the present embodiments and in the scope of the application in accordance with the spirit and principles of the present invention, and any modifications, equivalent substitutions, improvements, etc. are intended to be included within the scope of the present application.

Claims

1. An order distribution rechecking method is characterized by comprising the following steps:

Determining the type of the multicast wall for receiving the multicast review according to the number of the orders and the calculated average commodity number of the orders; the step of determining the type of the multicast wall for receiving the multicast review according to the number of orders and the calculated average commodity number of the orders comprises the following steps: if the number of orders is smaller than or equal to a preset first threshold value and the average commodity number of the orders is smaller than or equal to a preset second threshold value, determining that the type of the sub-broadcasting wall receiving sub-broadcasting review is a small vertical sub-broadcasting wall; if the number of orders is larger than a preset first threshold value and the average commodity number of the orders is smaller than or equal to a preset second threshold value, determining that the type of the multicast wall for receiving the multicast review is a large vertical multicast wall; if the average commodity number of the order is larger than a preset second threshold value, determining that the type of the multicast wall for receiving the multicast review is a horizontal multicast wall;

operating a corresponding sub-broadcasting rechecking process according to the type of the sub-broadcasting wall to obtain the sub-broadcasting information of each order generated after sub-broadcasting rechecking; the step of running the corresponding sub-cast rechecking process according to the type of the sub-cast wall comprises the following steps: if the type of the sub-broadcasting wall for receiving sub-broadcasting rechecking is a small vertical sub-broadcasting wall, running a sub-broadcasting rechecking process according to commodities; if the type of the sub-broadcasting wall for receiving sub-broadcasting rechecking is a large vertical sub-broadcasting wall, running a sub-broadcasting rechecking process according to commodities; if the type of the multicast wall for receiving the multicast recheck is a horizontal multicast wall, running the multicast recheck process according to the grid openings; each order distribution information comprises the order number, the commodity identification code and the commodity quantity, and the order distribution information is stored in the order database.

2. The method of claim 1, wherein the per-item multicast review process comprises:

determining an order number of an order to which the current commodity belongs and a corresponding grid according to the commodity identification code, displaying each virtual grid corresponding to the order number to which the current commodity belongs in a set virtual distribution wall, and displaying the commodity identification code of the current commodity and the commodity number of the current commodity in each virtual grid;

3. The method of claim 1, wherein the per-bin multicast review process comprises:

acquiring a grid port identification code of a current grid port, wherein the current grid port is one grid port of the multicast wall corresponding to the type of the multicast wall;

4. A method according to any one of claims 1 to 3, wherein the step of determining the binding relationship between each order number and the allocated portal for each order further comprises binding with the allocated turnover container, and wherein the step of determining the binding relationship between each order number, the allocated portal for each order, and the turnover container comprises:

firstly distributing grid openings for each order according to the acquired order set corresponding to the current picking container;

sequentially obtaining a grid identification code of a grid and a container identification code of an allocated turnover container, binding the order number corresponding to the grid, the grid and the allocated turnover container, and returning to the step for execution until all the order numbers, the grid and the turnover container are bound.

5. An order distribution rechecking device, which is characterized in that the device comprises:

The type determining module is used for determining the type of the multicast wall for accepting the multicast review according to the number of the orders and the calculated average commodity number of the orders; the step of determining the type of the multicast wall for receiving the multicast review according to the number of orders and the calculated average commodity number of the orders comprises the following steps: if the number of orders is smaller than or equal to a preset first threshold value and the average commodity number of the orders is smaller than or equal to a preset second threshold value, determining that the type of the sub-broadcasting wall receiving sub-broadcasting review is a small vertical sub-broadcasting wall; if the number of orders is larger than a preset first threshold value and the average commodity number of the orders is smaller than or equal to a preset second threshold value, determining that the type of the multicast wall for receiving the multicast review is a large vertical multicast wall; if the average commodity number of the order is larger than a preset second threshold value, determining that the type of the multicast wall for receiving the multicast review is a horizontal multicast wall;

the sub-broadcasting re-checking execution module is used for running a corresponding sub-broadcasting re-checking process according to the type of the sub-broadcasting wall to obtain the sub-broadcasting information of each order generated after sub-broadcasting re-checking; the step of running the corresponding sub-cast rechecking process according to the type of the sub-cast wall comprises the following steps: if the type of the sub-broadcasting wall for receiving sub-broadcasting rechecking is a small vertical sub-broadcasting wall, running a sub-broadcasting rechecking process according to commodities; if the type of the sub-broadcasting wall for receiving sub-broadcasting rechecking is a large vertical sub-broadcasting wall, running a sub-broadcasting rechecking process according to commodities; if the type of the multicast wall for receiving the multicast recheck is a horizontal multicast wall, running the multicast recheck process according to the grid openings; each order distribution information comprises the order number, the commodity identification code and the commodity quantity.

6. The apparatus of claim 5, wherein the multicast review execution module comprises:

the sub-broadcasting rechecking module is used for acquiring the commodity identification code of the current commodity, wherein the current commodity is one commodity loaded in the current commodity sorting container; determining an order number of an order to which the current commodity belongs and a corresponding grid according to the commodity identification code, displaying each virtual grid corresponding to the order number to which the current commodity belongs in a set virtual distribution wall, and displaying the commodity identification code of the current commodity and the commodity number of the current commodity in each virtual grid; acquiring grid port distribution completion information aiming at the current commodity, wherein the grid port distribution completion information represents information of placing the current commodity in a turnover container corresponding to a grid port according to the commodity number of the current commodity displayed in the virtual grid port; subtracting the commodity number of the current commodity from the order set, and adding the commodity number of the current commodity to the set order distribution information; returning to the step of acquiring the commodity identification code of the current commodity until all the commodities loaded in the current commodity sorting container are processed;

7. A computer readable storage medium having stored thereon computer instructions, which when executed by a processor, implement the order distribution review method of any of claims 1 to 4.

8. An electronic device comprising at least the computer-readable storage medium of claim 7, further comprising a processor;

the processor is configured to read the executable instructions from the computer readable storage medium and execute the instructions to implement the order distribution review method of any one of claims 1-4.