CN113222511A - Construction method of cross-border e-commerce warehousing frequency - Google Patents

Abstract

The invention relates to a construction method of cross-border e-commerce storage frequency, which comprises the following steps: establishing timing tasks of corresponding times based on different configuration information required by different clients; starting and executing corresponding timing tasks in a timing mode based on the configuration information, and executing batch to create different types of waves for all orders which meet the conditions of the configuration information in batch; acquiring a wave task actively applied by an operator through a PDA and issuing the wave task to a storage end for off-shelf processing; and acquiring the picking information of the order finished by off-shelf and carrying out corresponding statistical display. The invention has the beneficial effects that: through the flexible configuration of the automatic wave-time task, various combination condition configurations are supported, wave-time order aggregation and commodity inventory allocation logics are integrated, orders are aggregated efficiently and quickly to form wave times, and commodity traceability and attribute division are guaranteed; the design realization that the PDA actively applies for the wayward task and issues paperless off-shelf is adopted, so that managers can know the operation condition of the warehouse and adjust in time, and a rapid batch operation mode is added.

Description

Construction method of cross-border e-commerce warehousing frequency

Technical Field

The invention belongs to the technical field of E-commerce warehouse allocation, and particularly relates to a construction method of cross-border E-commerce warehouse storage frequency.

Background

At present, cross-border e-commerce market competition is intense, high efficiency and accuracy of warehouse operation become important links for improving service quality, and meanwhile, the continuous rise of warehouse operation cost is also a very big challenge. But the conventional warehouse delivery frequent mode at present has a single replenishment form, and a stock area can not be directly placed off shelves: the warehouse strictly complies with the conditions that the warehouse is only put off the shelf from the goods picking area, the goods preparation area is only used for storing goods, goods to be taken out of the warehouse are supplemented to the operation area when needed, the goods supplementation is heavy work, a large number of goods are transferred to the goods picking area, the goods positions in the goods picking area are small, the goods are scattered to be put on the shelf to different vacant goods picking areas, the operation amount is large, meanwhile, the position can be misplaced to cause the problem of putting off the shelf to be increased, meanwhile, part of the goods which are just completed by the goods supplementation are immediately picked in the operation area to be put off the shelf again, and operators feel that the labor is repeated, the time is wasted.

The generation of the wave times in batches needs manual work, and part of the e-commerce requirements still need manual creation of the wave times: the order is created in the form of order by manually selecting conditions required by manually distinguishing different customers according to the distribution condition of the order before operation every day, and each e-commerce customer is required to be manually created individually, the order generation is only generated for a picking area at present, and the orders of the single products, the same products and the sundries are created according to multiple dimensions of goods in the picking area, a delivery channel, an order time range and an order quantity. (the single-product frequency, namely all orders in the frequency have only one SKU and the quantity is 1, the same-product frequency, namely all orders in the frequency have the same quantity and the same type of the SKU, and the mixed-product frequency, namely all orders in the frequency have irregular SKU types and quantity).

The manual single wave number support is realized by firstly manually searching an order according to an order query condition, then manually selecting the order needing to be created in batches or one by one to execute the generated wave number, and then selecting the wave number type to execute operation, wherein the manual wave number is used for compensating the order which cannot be created by analyzing the automatic wave number, and the manual wave number is a compensation type operation mode.

The conventional mode of placing the goods on shelves is to print the goods picking orders on a PC (personal computer) in batches, then the goods picking orders are distributed to operators to use a PDA (personal digital assistant) to perform the placing operation, paper consumables are wasted more, and meanwhile the operators need to wait for the printed goods picking orders. And for single-product single-piece orders, the operation mode is highly repeated, and the efficiency is not high.

The warehouse operation efficiency of the same warehouse which meets different standard operation requirements of a plurality of cross-border e-commerce is low due to the above reasons, and the requirement of high-speed development of the cross-border e-commerce cannot be met.

Disclosure of Invention

In order to solve the problems of low efficiency and inconvenient operation in the prior art, the invention provides a construction method of cross-border e-commerce warehousing frequency, which has the characteristics of higher efficiency, more convenient operation and the like.

According to the specific embodiment of the invention, the construction method of the cross-border e-commerce warehousing wave number comprises the following steps:

establishing timing tasks of corresponding times based on different configuration information required by different clients;

starting and executing corresponding timing tasks in a timing mode based on the configuration information, and executing batch to create different types of waves for all orders which meet the conditions of the configuration information in batch;

acquiring a wave task actively applied by an operator through a PDA and issuing the wave task to a storage end for off-shelf processing;

and acquiring the picking information of the order finished by off-shelf and carrying out corresponding statistical display.

Further, the creating of the timing tasks of the corresponding times based on the different requirement configuration information of the different clients of the user comprises:

integrating multiple creating wave order conditions and wave order types;

executing the wave times at specified time or repeatedly executing the wave times at set intervals and fixed periods;

and constructing a visual monitoring interface, and displaying the created wave number task list and the execution condition so as to give an alarm to corresponding personnel when wave number execution fails.

Further, the step of starting and executing the corresponding timing task based on the configuration information at regular time, and the step of executing batch to create different types of waves for all orders meeting the conditions of the configuration information in batch comprises:

starting to execute order aggregation triggered according to the configured timing task when the timing task is triggered, and inquiring the order meeting all conditions to mark the task;

carrying out inventory allocation on the task marking order;

aggregating orders with the same attribute in a class of wave based on a commodity inventory distribution rule and a timing task condition;

and sorting the goods according to the distribution mode of the goods positions in the wave times.

Further, the acquiring and issuing the wave time task actively applied by the operator through the PDA includes:

inquiring the relevant wave type of the area based on the area, and pushing the corresponding wave type of the area to the PDA;

displaying the number of the wave times, the bar code of the commodity, the corresponding goods position and the quantity of the goods placed on the shelves;

and acquiring a submitted wave-order off-shelf result, and automatically applying for the next wave-order in the same region and the same wave-order type.

Further, the acquiring the picking information of the order finished by the shelf-off and performing corresponding statistical display comprises:

the whole operation flow node of the wave order basic information wave order is displayed, and the time length for putting off the shelf of the wave order is displayed;

and carrying out batch operation on the single-product single-piece wave times in the wave time dimension.

The invention has the beneficial effects that: through the flexible configuration of the automatic wave-time task, various combination condition configurations are supported, wave-time order aggregation and commodity inventory allocation logics are integrated, orders are aggregated efficiently and quickly to form wave times, and commodity traceability and attribute division are guaranteed; through the design realization that the PDA actively applies for the wayward task and issues paperless off-shelf, the paper consumption is saved, the working efficiency is improved, a manager can know the operation condition of the warehouse and adjust in time, a rapid batch operation mode is added, and the accuracy of operation can be ensured for high-homogeneity single-product single-piece orders.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a flow diagram of a method for building a cross-border e-commerce warehousing transaction provided in accordance with an exemplary embodiment;

FIG. 2 is a flow diagram providing for batch creation of different types of waves according to an exemplary embodiment;

FIG. 3 is a flow diagram providing for PDA off-shelf according to an exemplary embodiment;

FIG. 4 is a creation interface for a wayside timed task provided in accordance with an exemplary embodiment;

FIG. 5 is an operational interface of a PDA provided in accordance with an exemplary embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be described in detail below. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be derived by a person skilled in the art from the examples given herein without any inventive step, are within the scope of the present invention.

Referring to fig. 1, an embodiment of the present invention provides a method for constructing a cross-border e-commerce warehouse frequency, which specifically includes the following steps:

101. establishing timing tasks of corresponding times based on different configuration information required by different clients;

102. starting and executing corresponding timing tasks in a timing mode based on the configuration information, and executing batch to create different types of waves for all orders which meet the conditions of the configuration information in batch;

103. acquiring a wave task actively applied by an operator through a PDA and issuing the wave task to a storage end for off-shelf processing;

104. and acquiring the picking information of the order finished by off-shelf and carrying out corresponding statistical display.

Specifically, the running times are also called the unloading times, and as the name suggests, the running times are the core flow of warehouse operation, after a large number of orders of an e-commerce are pushed to a warehouse, the warehouse adopts a method for combining regular orders into one running time so as to form batch unloading and improving operation, and the method is applied to the flow of warehouse-out operation of a WMS warehouse. According to design requirements, the implementation of the wave frequency can be automatically started only by configuring the wave frequency task which is automatically created in advance in the operation process, and the subsequent process can automatically finish the next process without manual intervention basically:

firstly, configuring a timing task for automatically creating a wave number according to different requirements of different clients;

after configuration is completed, the wave time task can start execution batch at regular time according to the configuration information to carry out batch creation of different types of wave times on all orders which accord with the configuration conditions;

after the wave times are established, an operator can actively apply for the wave time task through a PDA (palm computer);

and the operator starts to carry out the shelf-off operation after receiving the wave time task. Therefore, flexible configuration of automatic wave-time tasks is realized, various combination condition configurations are supported, manual intervention is not needed after configuration, wave-time order aggregation and commodity inventory allocation logic are not needed, orders are aggregated efficiently and quickly to form wave times, and traceability and attribute division of commodities are guaranteed; the design of the paperless lower frame is realized, the paper consumption is saved, and the working efficiency is improved; and the wave time management operation node is clear, and clear operating efficiency of giving warehouse manager demonstrates in statistics man-hour, and the manager of being convenient for knows warehouse operation situation and adjusts in time, increases swift batch operation mode, can skip the repeated operation raise the efficiency on the accurate basis of guaranteeing the operation to the single article order form of high homogeneity.

As a possible implementation manner of the above embodiment, referring to fig. 2 to 5, the creating of the timing tasks of the corresponding times based on the different requirement configuration information of the different clients includes:

integrating multiple creating wave order conditions and wave order types;

executing the wave times at specified time or repeatedly executing the wave times at set intervals and fixed periods;

constructing a visual monitoring interface and displaying the created wave-time task list and the execution condition;

and when the wave-time execution fails, alarming corresponding personnel.

Starting and executing corresponding timing tasks in a timing mode based on the configuration information, and executing batch to create different types of waves for all orders meeting the conditions of the configuration information in a batch mode, wherein the steps comprise:

starting to execute order aggregation triggered according to the configured timing task when the timing task is triggered, and inquiring the order meeting all conditions to mark the task;

carrying out inventory allocation on the task marking order;

aggregating orders with the same attribute in a class of wave based on a commodity inventory distribution rule and a timing task condition;

and sorting the goods according to the distribution mode of the goods positions in the wave times.

The method for acquiring and issuing the wave time task actively applied by the operator through the PDA comprises the following steps:

inquiring the relevant wave type of the area based on the area, and pushing the corresponding wave type of the area to the PDA;

displaying the number of the wave times, the bar code of the commodity, the corresponding goods position and the quantity of the goods placed on the shelves;

and acquiring a submitted wave-order off-shelf result, and automatically applying for the next wave-order in the same region and the same wave-order type.

The step of obtaining the picking information of the orders finished by the off-shelf PDA and carrying out corresponding statistical display comprises the following steps:

the whole operation flow node of the wave order basic information wave order is displayed, and the time length for putting off the shelf of the wave order is displayed;

and carrying out batch operation on the single-product single-piece wave times in the wave time dimension.

Specifically, the wave number implementation process may include:

1) integrated diversification creates the conditions of order: the secondary development tasks can be defined according to the combination conditions of warehouses, e-commerce, transportation channels, order time ranges, different warehouse areas (automatic warehouse analysis areas, warehouse area designation/elimination areas), designated SKUs, order recipient provinces/cities, large-head software, inventory types (good products/temporary commodities and the like).

2) A wave order category can be created: the method supports single-product frequency, same-product frequency, sundry frequency and stock area single-product frequency, supports lower limit and upper limit configuration of order quantity of each frequency, and can configure different types of frequency tasks in the same frequency task to create different types of multiple frequencies.

3) The wave number execution cycle may be executed at a specified time, or may be repeatedly executed at a fixed interval.

4) And providing a wave-order task visual monitoring interface, displaying the created wave-order task list and the execution condition, and generating wave-order quantity including order quantity influenced by wave-order, wave-order execution state, execution starting time and execution ending time and the like.

5) And an alarm function is provided, and when the execution of the task of the wave number fails, the corresponding personnel is reminded to alarm by sending a message through a short message and a nail.

The order-pass aggregation logic may include:

1) order collection: when the timing task is triggered, the order aggregation is triggered according to the configured wave-time task, the wave-time order meeting all conditions is inquired through an SQL statement, and task marking is carried out to prepare for stock distribution.

2) Distributing the stock: the task marking orders are subjected to inventory allocation, inventory of single spare parts in a spare area is gathered, whether the number of the orders can reach the lower limit of the order quantity requirement of the spare area and the spare area has enough inventory allocation meeting the conditions is judged, if the orders can reach the lower limit of the order requirement of the spare area, the inventory allocation is carried out by searching the inventory in the spare area, if the orders cannot meet the requirements, the orders are transferred to a sorting area for allocation of the inventory, the inventory allocation principle conditions firstly specify commodity batches according to the orders, if the batches are not specified, the inventory is allocated according to the first-in first-out, and all the remaining task marking orders are allocated.

3) Order aggregation generation wave times: according to a commodity inventory distribution rule, orders with the same attribute are gathered in a category of times through SQL according to the times task condition, the gathering sequence is that the orders of a single item stocking area are gathered, the orders of a single item are gathered, the orders of the same item are gathered, and then the remaining orders are gathered to be the orders of sundry items. The wave time task is provided with a maximum single amount and a minimum single amount for configuring single wave times, during aggregation, the single amount of each wave time is firstly aggregated according to the configured maximum single amount of the wave times, the single amount is aggregated according to the actual single amount when the maximum single amount is not reached and the minimum single amount is exceeded, and if the single amount is lower than the minimum single amount, the aggregation is abandoned, and the aggregation of the mixed wave times of the next level is carried out.

4) Sorting the cargo positions of the order: after the order aggregation is completed, the order is sequenced in a distribution mode of goods positions in the order, so that the optimal picking route is ensured, the route moves according to the S-shaped route without returning, and the shelves are sequenced from top to bottom.

The PDA paperless operation may specifically include:

1) wave number claiming: on the premise that the wave times are established, the off-shelf staff firstly select the working area of the staff at the PDA, inquire the relevant wave time type of the area according to the area, and request the server after selecting the wave time type of the area, so that the server is to push the wave times corresponding to the area to the PDA.

2) Setting the wave times: after receiving the wave times, the wave times information is cached in the PDA and enters a wave times off-shelf interface, and the wave times number, the commodity bar code, the corresponding goods position and the off-shelf quantity are displayed. The personnel of putting down shelves according to the wave show information, pick the goods according to the precedence order of goods position and put down shelves, scan commodity bar code, goods position, confirm the quantity of putting down shelves can, so the bar code of putting down shelves, goods position, quantity are unusual directly to pass through PDA cache data direct check-up, need not interact with the server, improve scanning efficiency.

3) Wave number submission: and after the PDA finishes one off-shelf process, submitting the off-shelf results of the wave times to the server, automatically applying for the next wave time in the same area and the same wave time type, and jumping to a selection area interface to prompt selection of other wave times if the wave times are available.

When the wave frequency management is carried out, the whole operation flow nodes of the wave frequency order are displayed besides basic information of the wave frequency, the time length for putting down the shelf of the wave frequency is displayed, management personnel can know the operation condition of the warehouse conveniently, and the operation rhythm can be adjusted in time according to the reference.

4) Shortcut wave operation: aiming at the single-product single-piece wave frequency (namely, a batch of orders only has one SKU and each order only has one wave frequency), the order is completely homogenized, so that the design can carry out batch operation in the wave frequency dimension without being limited to unloading, and also comprises links of boxing, weighing and the like, batch operation is implemented, and the functions of skipping unloading, skipping boxing and skipping weighing are provided, thereby greatly improving the operation efficiency in the warehouse.

Referring to fig. 4 and 5, the content of creating the order may include information of a warehouse, information of an order customer, selection of a transportation channel, time, type and quantity of orders from and to the order, and a warehouse construction order, which can satisfy the construction of the existing warehouse order. The PDA operation interface can be designed to comprise information such as a number of times, a goods position, a commodity bar code, a corresponding bar code for display, a stock type, the quantity of shelves to be placed and the like, and meanwhile, the corresponding number of shelves to be placed is manually input to be placed. Thereby being convenient for the user to carry out more flexible shelf-off operation.

According to the construction method of the cross-border e-commerce warehousing wave frequency provided by the embodiment of the invention, the space is planned according to the warehouse area, the replenishment logic is adjusted perfectly, the application range of batch wave frequency is expanded highly to achieve the effect of flexible configuration, the wave frequency is automatically analyzed and created, the full coverage of orders in the warehouse is achieved, and meanwhile, the wave frequency is fully covered. Finally, the direct racking of the stock area of the warehouse is supported by a target for realizing double improvement of the operating efficiency and the quality of the warehouse, so that the operation of the replenishment operation is reduced, and the efficiency is improved; the wave number creation tasking is realized, and the trouble of manually creating wave numbers every day is avoided to the maximum extent; realize no paper ripples time undercarriage, the relative tradition is printed paper and is picked the manifest undercarriage and has been saved the paper consumptive material comprehensively, has avoided the paper to pick the manifest brokenly simultaneously, distributes easy chaotic problem.

It will be understood by those skilled in the art that all or part of the steps carried by the method for implementing the above embodiments may be implemented by hardware related to instructions of a program, which may be stored in a computer readable storage medium, and when the program is executed, the program includes one or a combination of the steps of the method embodiments.

In addition, functional units in the embodiments of the present invention may be integrated into one processing module, or each unit may exist alone physically, or two or more units are integrated into one module. The integrated module can be realized in a hardware mode, and can also be realized in a software functional module mode. The integrated module, if implemented in the form of a software functional module and sold or used as a stand-alone product, may also be stored in a computer readable storage medium.

The storage medium mentioned above may be a read-only memory, a magnetic or optical disk, etc.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

What has been described above includes examples of one or more embodiments. It is, of course, not possible to describe every conceivable combination of components or methodologies for purposes of describing the aforementioned embodiments, but one of ordinary skill in the art may recognize that many further combinations and permutations of various embodiments are possible. Accordingly, the embodiments described herein are intended to embrace all such alterations, modifications and variations that fall within the scope of the appended claims. Furthermore, to the extent that the term "includes" is used in either the detailed description or the claims, such term is intended to be inclusive in a manner similar to the term "comprising" as "comprising" is interpreted when employed as a transitional word in a claim. Furthermore, any use of the term "or" in the specification of the claims is intended to mean a "non-exclusive or".

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (5)

1. A construction method of cross-border e-commerce warehousing frequency is characterized by comprising the following steps:

establishing timing tasks of corresponding times based on different configuration information required by different clients;

starting and executing corresponding timing tasks in a timing mode based on the configuration information, and executing batch to create different types of waves for all orders which meet the conditions of the configuration information in batch;

acquiring a wave task actively applied by an operator through a PDA and issuing the wave task to a storage end for off-shelf processing;

and acquiring the picking information of the order finished by off-shelf and carrying out corresponding statistical display.

2. The method for constructing cross-border e-commerce warehouse wave times according to claim 1, wherein the step of creating timing tasks of corresponding wave times based on different configuration information required by different customers comprises the following steps:

integrating multiple created wave order conditions and multiple wave order types;

executing the wave times at specified time or repeatedly executing the wave times at set intervals and fixed periods;

and constructing a visual monitoring interface, and displaying the created wave number task list and the execution condition so as to give an alarm to corresponding personnel when wave number execution fails.

3. The method for constructing cross-border e-commerce warehouse wave times according to claim 1, wherein the step of starting and executing corresponding timing tasks in a timing mode based on the configuration information, and the step of executing batch creation of different types of wave times for all orders meeting the conditions of the configuration information in a batch mode comprises the following steps:

starting to execute order aggregation triggered according to the configured timing task when the timing task is triggered, and inquiring the order meeting all conditions to mark the task;

carrying out inventory allocation on the task marking order;

aggregating orders with the same attribute in a class of wave based on a commodity inventory distribution rule and a timing task condition;

and sorting the goods according to the distribution mode of the goods positions in the wave times.

4. The method for constructing cross-border e-commerce warehouse wave times as claimed in claim 1, wherein the acquiring and issuing wave time tasks actively applied by an operator through a PDA comprises:

inquiring the relevant wave type of the area based on the area, and pushing the corresponding wave type of the area to the PDA;

displaying the number of the wave times, the bar code of the commodity, the corresponding goods position and the quantity of the goods placed on the shelves;

and acquiring a submitted wave-order off-shelf result, and automatically applying for the next wave-order of the same region and the same wave-order type.

5. The method for constructing cross-border e-commerce warehouse information according to any one of claims 1 to 4, wherein the step of obtaining the order picking information finished on the shelves and performing corresponding statistical display comprises the following steps:

the whole operation flow node of the wave order basic information wave order is displayed, and the time length for putting off the shelf of the wave order is displayed;

and carrying out batch operation on the single-product single-piece wave times in the wave time dimension.

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