CN110298618B

CN110298618B - Wave order off-shelf task generation method and device, storage medium and electronic equipment

Info

Publication number: CN110298618B
Application number: CN201910602329.8A
Authority: CN
Inventors: 于浩然; 曾江海; 龚亮; 林辉明
Original assignee: Shanghai Zhongtongji Network Technology Co Ltd
Current assignee: Shanghai Zhongtongji Network Technology Co Ltd
Priority date: 2019-07-05
Filing date: 2019-07-05
Publication date: 2023-06-09
Anticipated expiration: 2039-07-05
Also published as: CN110298618A

Abstract

The application relates to a wave order off-shelf task generating method, a device, a storage medium and electronic equipment, which belong to the technical field of logistics, and the method comprises the steps of determining a two-section order to be processed; ordering the multi-product orders in the two-stage orders based on the payment time sequence, sequentially selecting orders of a first order number from the obtained sequence, and generating multi-product wave times to be processed; when an operator applies for the shelving task aiming at any multi-product wave, a section of package of the shelving task is determined according to the information of the sub-warehouse area in the application, and a container used by the shelving task is distributed to generate the wave shelving task. According to the method and the device, the two-section order is used for creating the wave times, when an operator applies for the putting-in task to a certain wave time, the wave times are cut to generate the wave time putting-in task of the operator, so that the operator only needs to put-in operation in a corresponding range, the working efficiency is improved, and the quick bag collection of the two-section package is integrally facilitated.

Description

Wave order off-shelf task generation method and device, storage medium and electronic equipment

Technical Field

The invention belongs to the technical field of logistics, and particularly relates to a method and a device for generating a wave-order off-shelf task, a storage medium and electronic equipment.

Background

In the operation of the centralized warehouse management, the method involves the operation of taking down the package which is already put on the shelf so as to carry out the two-section package collecting operation. In order to ensure the loading efficiency, the packing and loading mode generally adopts a random loading mode in the operation of the shipping and storage management, and the loading mode can cause certain difficulty to the two-section packed collection, and the mode of wave times unloading is adopted in the collection operation aiming at the problem.

In the existing wave-time racking, only one section of package meeting the racking condition at present is pushed out to form a racking task, and the racking task generated by the mode is easy to occur in the process of executing, so that the condition that the package collection needs a long time to be completed, and finally the package collection operation efficiency is low.

Disclosure of Invention

In order to overcome the problems existing in the related art at least to a certain extent, the method, the device, the storage medium and the electronic equipment for generating the wave-order off-shelf tasks are beneficial to generating better wave-order off-shelf tasks so as to improve the packet collecting efficiency.

In order to achieve the above purpose, the present application adopts the following technical scheme:

in a first aspect of the present invention,

the application provides a generation method of a wave number off-shelf task, which comprises the following steps:

determining a two-section order to be processed;

ordering the multiple orders in the two orders based on the payment time sequence, sequentially selecting orders of a first order number from the obtained sequence, and generating multiple orders to be processed;

when an operator applies for the shelving task aiming at any multi-product wave number, a section of package of the shelving task is determined according to the information of the sub-warehouse area in the application, and a container used by the shelving task is distributed to generate the wave number shelving task.

Optionally, determining a section of package of the off-shelf task based on the job sub-pool area information in the task application request, including,

analyzing the two-section orders contained in the multiple-product wave number to obtain one-section package information contained in each two-section order;

and comparing the first-stage package information with the information of the working sub-warehouse area, and determining the first-stage package of which the bin positions are positioned in the working sub-warehouse area in the multiple product wave passes as the first-stage package of the shelf-off task.

Optionally, the containers used for the task of distributing the off-shelf, including,

judging whether the number of the frame to be put down is allocated for the multiple product wave,

if the allocation is carried out, determining the container with the allocated frame number of the lower frame in the containers belonging to the job sub-warehouse area as a container used by the lower frame task;

if the operation sub-warehouse area is not allocated, determining the idle container with the minimum frame number of the lower frame in the containers belonging to the operation sub-warehouse area as a container used by the lower frame task.

Optionally, the generating method further comprises,

ordering the single product orders in the two-section orders based on the payment time sequence, sequentially selecting orders of a second order number from the obtained sequence, and generating Shan Pinbo times to be processed;

when an operator applies for the shelving task for any Shan Pinbo times, all the sections of the Shan Pinbo times are wrapped to be used as one section of the shelving task so as to generate the wave shelving task.

In a second aspect of the present invention,

the application provides a generating device of wave time off-shelf task, including:

the determining module is used for determining the two-section order to be processed;

the multi-product wave generation module is used for sequencing the multi-product orders in the two-section orders based on the payment time sequence, sequentially selecting orders of a first order number from the obtained sequence, and generating multi-product waves to be processed;

shan Pinbo secondary generation module, which is used for sorting the single product orders in the two-section orders based on the payment time sequence, sequentially selecting the orders of the second order number from the obtained sequence, and generating Shan Pinbo times to be processed;

the first task generating module is used for determining a section of package of the shelving task according to the information of the sub-warehouse area in the application when an operator applies for the shelving task for any multi-product wave number, and distributing containers used by the shelving task to generate the wave number shelving task;

and the second task generating module is used for taking all the one-section packages in Shan Pinbo times as one-section packages of the shelving task when an operator applies for the shelving task for any Shan Pinbo times so as to generate the wave-time shelving task.

In a third aspect of the present invention,

the present application provides a readable storage medium having stored thereon an executable program which when executed by a processor implements the steps of the method described above.

In a fourth aspect of the present invention,

the application provides an electronic device, comprising:

a memory having an executable program stored thereon;

and a processor for executing the executable program in the memory to implement the steps of the method described above.

The application adopts the technical scheme, possesses following beneficial effect at least:

the two-section order is divided based on the payment time sequence to generate the to-be-processed wave number, when an operator applies for the task aiming at the corresponding wave number, the wave number is cut according to the sub-stock area which the operator takes charge of to generate the wave number putting task of the operator, so that the operator only needs to operate in a corresponding range, the working efficiency is improved, and the quick bag collection of the two-section package is integrally facilitated.

Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

Drawings

The accompanying drawings are included to provide a further understanding of the technical aspects or prior art of the present application and constitute a part of this specification. The drawings, which are used to illustrate the technical solution of the present application, together with the embodiments of the present application, but do not limit the technical solution of the present application.

FIG. 1 is a schematic flow chart of a method for generating a wave-order off-shelf task according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a wave-order off-shelf task generating device according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of an electronic device according to an embodiment of the invention.

Detailed Description

In order to facilitate understanding of the technical solutions of the present application, some concepts referred to in the present application will be described first.

And (3) wrapping: the method mainly refers to logistics packages of domestic section waybills, and usually the same buyer can have a plurality of sections of packages in different time periods to arrive at a warehouse.

Two-section package: the method mainly refers to the logistics package of the international section, which is usually a large package integrated by a plurality of first-section packages of the same buyers, wherein the plurality of first-section packages are required to be wound together by a winding film, and the second-section packages are products after the package collecting operation.

Two-stage order: an order corresponding to the two-section package.

Multiple product order: refers to a two-section order corresponding to a two-section package comprising a plurality of one-section packages.

Order of single product: refers to a two-section order corresponding to a two-section package which only contains one section package.

Wave times: one job lot of the multiple orders is summarized, and this job lot is often referred to as a "wave number".

Multiple product wave times: the two orders in the wave times are all wave times of the multiple orders.

Shan Pinbo times: the two orders in the wave time are all wave times of single product orders.

A warehouse area: one physical warehouse area in the shipping warehouse can be configured with country and business room attributes.

Sub-reservoir area: the stock area is cut into a plurality of small stock areas according to a certain rule, and the stock areas are generally equally divided according to the number of shelves.

Lower frame number: when the multi-product wave number putting-in task is executed, a container is needed, the container can be a supermarket shopping trolley, a woven bag or a plastic frame, and the corresponding number of the container is called a putting-in frame number.

Sorting wall: the distributing tool used in distributing can be a special and professional sorting wall or a goods shelf with a certain number of grid openings, wherein the grid openings refer to a container for containing one section of package, and one grid opening only aims at one two sections of package.

The following will describe embodiments of the present invention in detail with reference to the drawings and examples, thereby solving the technical problems by applying technical means to the present invention, and realizing the corresponding technical effects can be fully understood and implemented accordingly. The embodiments and the features in the embodiments can be combined with each other under the condition of no conflict, and the formed technical schemes are all within the protection scope of the invention.

As described in the background art in the present application, in the existing wave time lower frame, only a section of package meeting the lower frame condition is directly pushed out to form the lower frame wave time task, an operator searches a corresponding package according to the task to go to the full warehouse area to lower the frame, and allocates the package to the lower frame package, so that the condition that the package collection needs a long time to be aligned easily occurs, and finally the package collection operation efficiency is low.

In the technical scheme of the application, a plurality of wave orders are created firstly based on the two-section order pushed by the system, when an operator applies for a putting-in task aiming at a certain wave order, the wave orders are cut according to the operation area which is responsible for the operator to generate the wave-in task of the operator, so that the operator only needs to put-in the corresponding range for a section of package, the working efficiency is improved, and then the operators in different operation areas cooperatively process the same wave order, thereby being beneficial to the quick package collection of the two-section package on the whole.

Fig. 1 is a flow chart of a method for generating a wave-order off-shelf task according to an embodiment of the present application.

As shown in fig. 1, the method for generating the wave-time off-shelf task includes the following steps:

step S110 is first performed to determine a two-segment order to be processed.

For a certain warehouse area, two-section orders pushed by an external system are large-batch, and in order to facilitate subsequent processing, the subsequent to-be-processed two-section orders need to be determined from the pushed two-section orders. For example, a second order pushed by the system is received, and the second order that is paid and completed in the last 7 days is determined to be the second order to be processed.

As described in the foregoing application, the two-stage order includes a multi-product order and a single-product order, and the two orders are processed separately in the application, and are described separately below.

For multiple product orders

As shown in step S120 in fig. 1, multiple orders in the two-stage order to be processed are ordered based on the payment time sequence, and orders of the first order number are sequentially selected from the obtained sequence, so as to generate multiple orders to be processed.

It should be noted that, the size of the first order quantity is related to the size of the actual multi-product order (corresponding to the included number of packages) and the comprehensive processing efficiency of personnel, and the first order quantity is generally not greater than 18 after the actual statistical optimization. For example, in a specific embodiment, the first order number is 18, that is, from the ordered multi-product order sequence, each 18 orders are sequentially divided into multiple product waves, and finally, a plurality of multiple product waves are generated, and each wave is correspondingly allocated with a respective wave number.

In addition, it should be noted that in step S120, the number of orders in the multi-product order sequence may not be an integer multiple of the first order number, and in actual operation, the last order less than the first order number may be directly divided into one time, or the orders may be returned and used again as the two-segment order pushed by the external system for the next determination in step S110.

And then, step S130 is carried out, when working personnel apply for the shelving task for any multi-product wave to be processed, a section of package of the shelving task is determined according to the information of the sub-warehouse area in the application, and containers used by the shelving task are distributed to generate the wave shelving task.

In the application scene of the application, the storage area is divided into a plurality of sub-storage areas according to the number of shelves, and each sub-storage area is correspondingly provided with a respective off-shelf operator. For a certain multi-product wave number to be processed, the operators in each sub-warehouse area respectively send out task applications for the wave number so as to finish the putting of the wave number in a cooperative manner.

The application sent by the operators in different sub-warehouse areas can contain the information of the sub-warehouse areas of the operators, the application determines a section of package of the shelving task according to the information of the sub-warehouse areas in the application, and in particular,

firstly, analyzing two-section orders contained in the multiple-product wave number to obtain one-section package information contained in each two-section order, wherein the one-section package information comprises bin information of one-section package; and comparing the obtained parcel information with the information of the job sub-warehouse area in the request, and determining the parcel of which the bin is positioned in the job sub-warehouse area in the multiple frequency as the parcel of the shelf-taking task.

And because of the characteristics of multiple product orders, containers used for the task of putting the shelf are also required to be allocated in order to realize the cooperative putting of operators in each sub-warehouse area on the same wave. In the application scene of the application, each sub-warehouse area is configured with the same number of containers, and the containers in different sub-warehouse areas use the same set of lower frame numbers, for example, the warehouse area is divided into two sub-warehouse areas A1 and A2, each sub-warehouse area is configured with 4 containers, the lower frame numbers of the containers in the sub-warehouse area A1 are respectively 1, 2, 3 and 4, and then the lower frame numbers of the containers in the sub-warehouse area A2 are respectively 1, 2, 3 and 4.

In step S130, when the worker applies for the task of putting off the shelf for any of the multiple product waves to be processed, the containers used for the task of putting off the shelf are allocated, specifically,

firstly, judging whether the number of the frame to be put down is allocated for the multiple product wave,

if the number of the work sub-warehouse is not allocated (namely, the number of the work sub-warehouse is the first time when the work is applied for by a worker in a sub-warehouse), the idle container with the smallest frame number of the work sub-warehouse is determined to be the container used by the work sub-warehouse. For example, the operator in the A1 sub-pool area applies for the task for the multiple product wave first, and if the containers with the lower frame numbers 1,3 and 4 in the A1 sub-pool area are idle, the container with the lower frame number 1 is determined as the container for the lower frame task.

If the allocation is performed (i.e., a job application is first performed by a person in a sub-pool area for the multiple product frequency), the container having the allocated drop frame number among the containers belonging to the sub-pool area is determined as the container used for the drop job. For example, when the worker in the A1 sub-warehouse performs a task application for the multiple product wave number for the first time and the assigned frame number of the lower frame is 1, when the worker in the A2 sub-warehouse performs a task application for the multiple product wave number, the container with the frame number of the lower frame 1 in the container belonging to the A2 sub-warehouse is determined as the container used for the lower frame task.

After step S130, for a plurality of product wave times, the racking tasks required to be executed by the operators in each sub-warehouse area are generated, and each racking task includes a section of package to be racking and a container for racking.

The worker performs the racking task, and uses the assigned container to transport the length of the shelved parcel to the sorting wall bound with the racking frame number of the used container for subsequent sorting. For example, for a certain wave, the operators in the sub-warehouse area A1 and the sub-warehouse area A2 execute respective shelf-unloading tasks, all use the containers with the shelf number of 1 to carry out shelf-unloading, and then a section of package after shelf-unloading is sent to the same sorting wall.

For single product orders

Because the two-section package corresponding to the single-section order only comprises one section package, the second-time package collection is not needed in the one-section package after the placing of the shelf, and therefore the sub-warehouse area division is not needed for Shan Pinbo times.

Specifically, for the order of the single product, first, as shown in step S140 in fig. 1, the order of the single product in the two-stage order to be processed is ordered based on the payment time sequence, and the order of the second order number is sequentially selected from the obtained sequence, so as to generate Shan Pinbo times to be processed. Because of the characteristics of the single product order, the second order quantity is generally greater than or equal to 40 and less than or equal to 70 through actual statistical optimization to ensure the actual efficiency.

And then, performing step S150, and when a worker applies for the shelving task for any single product wave, taking all the sections of packages in Shan Pinbo times as one section of packages of the shelving task to generate the wave shelving task. And further, a special operator can be configured to perform the task application in step S150 and perform subsequent task execution, i.e. the operator only performs the placing of the order of the single product, thereby further improving the efficiency.

According to the method for generating the wave-order putting task, the two-section order is divided based on the payment time sequence to generate the wave-order to be processed, when an operator applies for the task according to the corresponding wave-order, the wave-order is cut according to the sub-stock area responsible for the operator to generate the wave-order putting task of the operator, so that the operator only needs to operate in a corresponding range, the working efficiency is improved, and the quick bag collection of the two-section package is integrally facilitated.

Fig. 2 is a schematic structural diagram of a wave-order off-shelf task generating device according to an embodiment of the present invention. As shown in fig. 2, the wave-time off-shelf task generating device 2 includes:

a determining module 201, configured to determine a two-segment order to be processed;

the multiple-product-wave-number generation module 202 is configured to sort multiple-product orders in the two-stage orders based on the payment time sequence, sequentially select orders of a first order number from the obtained sequence, and generate multiple-product-wave-numbers to be processed;

shan Pinbo secondary generation module 203, configured to sort the single orders in the two orders based on the payment time sequence, sequentially select the orders of the second order number from the obtained sequence, and generate Shan Pinbo to-be-processed orders;

the first task generating module 204 is configured to determine a section of package of the shelving task according to the sub-pool area information in the application when the worker applies for the shelving task for any of the multiple product waves, and allocate a container used by the shelving task to generate the wave shelving task;

and the second task generating module 205 is configured to, when the worker applies for the shelving task for any single product wave, take all the packages of one segment of Shan Pinbo times as one segment of the shelving task, so as to generate the wave shelving task.

Further, the first task generation module 204 is specifically configured to,

when an operator applies for a shelf task aiming at any multi-product wave number, analyzing two-section orders contained in the multi-product wave number to obtain one-section package information contained in each two-section order, comparing the one-section package information with the information of a working sub-warehouse area, and determining one-section package of a warehouse position in the multi-product wave number in the working sub-warehouse area as one-section package of the shelf task;

if the allocation is performed, the container corresponding to the allocated lower frame number in the container belonging to the job sub-warehouse area is determined as the container for the lower frame task, and if the allocation is not performed, the idle container with the minimum lower frame number in the container belonging to the job sub-warehouse area is determined as the container for the lower frame task.

The specific manner in which the respective modules perform the operations in relation to the wave-order off-shelf task generating device 2 in the above-described related embodiment has been described in detail in the embodiment relating to the method, and will not be described in detail here.

In one embodiment, the present application provides a further readable storage medium having stored thereon an executable program which when executed by a processor performs the steps of the above method.

With respect to the readable storage medium in the above-described embodiments, a specific manner of performing program execution operations stored therein has been described in detail in the embodiments related to the method, and will not be described in detail herein.

Fig. 3 is a schematic structural diagram of an electronic device according to an embodiment of the present application, as shown in fig. 3, where the electronic device 3 includes:

a memory 301 on which an executable program is stored;

a processor 302 for executing an executable program in the memory 301 to implement the steps of the above method.

The specific manner in which the processor 302 executes the program in the memory 301 of the electronic device 3 in the above-described embodiment has been described in detail in the embodiment concerning the method, and will not be described in detail here.

The present invention is not limited to the above-mentioned embodiments, and any changes or substitutions that can be easily understood by those skilled in the art within the scope of the present invention are intended to be included in the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the protection scope of the claims.

Claims

1. The method for generating the wave number off-shelf task is applied to the operation management of the shipping bins and is characterized by comprising the following steps:

determining a two-section order to be processed;

when an operator applies for the racking task aiming at any multi-product wave number, determining a section of package of the racking task according to the information of the sub-warehouse area in the application, and distributing containers used by the racking task to generate the wave number racking task;

wherein determining a section of package of the off-shelf task based on the job sub-pool area information in the task application request comprises,

comparing the first section of package information with the information of the working sub-warehouse area, and determining the first section of package with the bin position in the working sub-warehouse area in the multiple product wave number as the first section of package of the shelf-off task;

the containers used for the task of distributing the off-shelf, including,

if the operation sub-warehouse area is not allocated, determining an idle container with the minimum frame number of the lower frame in the containers belonging to the operation sub-warehouse area as a container used by the lower frame task;

wherein, each operation sub-warehouse area is provided with the same number of containers, and the containers in different operation sub-warehouse areas use the same set of frame numbers;

wherein,,

one section of package refers to the logistics package of the domestic section of waybills;

the second-section package refers to a package integrated by the first-section package of the same buyer, and the second-section order refers to an order corresponding to the second-section package;

the multi-product order refers to a two-section order corresponding to a two-section package comprising a plurality of one-section packages;

the multiple product wave times refer to the wave times that two orders in the wave times are all the wave times of the multiple product orders.

2. The method of claim 1, wherein the generating method further comprises,

when an operator applies for the shelving task for any Shan Pinbo times, taking all the sections of packages in Shan Pinbo times as one section of packages of the shelving task to generate a wave shelving task;

wherein,,

the single-product order refers to a two-section order corresponding to a two-section package which only comprises one section package;

shan Pinbo times means that the two orders in the wave times are all wave times of single product orders.

3. The method according to claim 2, wherein the first amount of orders is not greater than 18; the second amount of orders is 40 or more and 70 or less.

4. The method of claim 1, wherein determining the pending two-piece order comprises,

receiving a two-section order pushed by the system,

and determining the two-section order of which the payment is completed in the latest appointed time as the two-section order to be processed.

5. The method of claim 4, wherein the contracted time is 7 days.

6. The utility model provides a generating device of wave time off-shelf task, is applied to the operation management of collection fortune storehouse, characterized in that includes:

the second task generating module is used for taking all the one-section packages in Shan Pinbo times as one-section packages of the shelving task when an operator applies for the shelving task for any Shan Pinbo times so as to generate a wave-time shelving task;

the containers used for the task of distributing the off-shelf, including,

wherein,,

7. A readable storage medium having stored thereon an executable program, which when executed by a processor, implements the steps of the method of any of claims 1-5.

8. An electronic device, comprising:

a memory having an executable program stored thereon;

a processor for executing the executable program in the memory to implement the steps of the method of any one of claims 1-5.