CN112150257B - Order processing method, cloud system, electronic device and storage medium - Google Patents

Abstract

The invention discloses an order processing method, a cloud system, electronic equipment and a storage medium, wherein an order combining strategy and an execution priority which are set by a user and are related to an order are received through a client; dividing the orders into a plurality of order sets with execution priorities according to the set order grouping strategy and the execution priorities; the client sends the order set containing the execution priority to a cloud system so that the cloud system can send corresponding execution commands to corresponding execution terminals; the order execution can be flexibly processed according to the user requirements, and the flexibility and the intelligence of order processing are improved; for the user side, the interactive experience of the user is improved.

Description

Order processing method, cloud system, electronic device and storage medium

Technical Field

The invention relates to the technical field of data processing, in particular to an order processing method, a cloud system, electronic equipment and a storage medium.

Background

With the rapid development of electronic commerce, people have higher and higher requirements for logistics services. In recent years, with the increasing of warehouse logistics scale, the demands for speed, efficiency and the like of warehouse order processing are increasing, and more warehouses begin to utilize robots to assist in manually completing the processing work of large batches of orders. The existing order processing methods are generally as follows: the control system dispatches a large number of business orders to form an order collection, the order collection is sent to the robot executing the tasks, then the robot arrives at an order processing area according to the order content, and warehouse staff complete the operation on the corresponding orders according to the prompt of a robot system interface. Although the order processing mode improves the processing efficiency of the large-batch warehouse orders, the processing mode is only limited to processing daily orders and cannot cope with various uncertainties possibly occurring in warehouse operation, and the order which needs to be processed temporarily due to the uncertainties is large in limitation and inflexible, and the individualized order operation requirements of warehouse operators are difficult to meet.

Disclosure of Invention

The invention provides an order processing method, a cloud system, electronic equipment and a storage medium, and aims to flexibly process execution of an order according to actual requirements of a user.

In a first aspect, the present invention provides an order processing method, where the order processing method includes: the client receives a group order strategy and an execution priority which are set by a user and are related to the order; dividing the orders into a plurality of order sets with execution priorities according to the set order grouping strategy and the execution priorities; and the client sends the order set containing the execution priority to a cloud system so that the cloud system can send a corresponding execution command to a corresponding execution terminal.

In a second aspect, the present invention provides an order processing apparatus, comprising: the setting module is used for receiving order-combining strategies and execution priorities which are set by a user and are related to orders; the processing module is used for dividing the orders into a plurality of order sets with execution priorities according to the set order grouping strategy and the execution priorities; and the issuing module is used for sending the order set containing the execution priority to a cloud system so that the cloud system can send a corresponding execution command to a corresponding execution terminal.

In a third aspect, the present invention provides a cloud system, where the cloud system may perform data interaction with the order processing apparatus to perform order processing operations; wherein the cloud system is configured to: receiving an order set which is sent by the order processing device and contains the execution priority, and always converting the order set with the highest execution priority into a plurality of executable command sets according to the execution priority corresponding to the order set; the command sets are sequentially issued to corresponding execution terminals; wherein the execution terminal includes: a terminal PDA and/or a plurality of robots and/or other executable devices that can execute commands and/or command processing devices that can assist the smart device in executing the nomenclature.

In a fourth aspect, the present invention provides an electronic device, including a memory and a processor, where the memory stores an order processing program executable on the processor, and the order processing program is executed by the processor to perform the order processing method.

In a fifth aspect, the present invention provides a computer-readable storage medium having stored thereon an order processing program executable by one or more processors to implement the steps of the order processing method.

The invention relates to an order processing method, a cloud system, electronic equipment and a storage medium, which receive an order-forming strategy and an execution priority which are set by a user and are related to an order through a client; dividing the orders into a plurality of order sets with execution priorities according to the set order grouping strategy and the execution priorities; the client sends the order set containing the execution priority to a cloud system so that the cloud system can send corresponding execution commands to corresponding execution terminals; the order execution can be flexibly processed according to the user requirements, and the flexibility and the intelligence of order processing are improved; for the user side, the interactive experience of the user is improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

In the drawings: FIG. 1 is a flow chart illustrating an embodiment of an order processing method according to the present invention.

FIG. 2 is a signal flow diagram illustrating the execution of one embodiment of the order processing method of the present invention.

FIG. 3 is an interface diagram of an embodiment of a user interface in the order processing method of the present invention.

FIG. 4 is an interface diagram of another embodiment of a user interface for an order processing method according to the present invention.

FIG. 5 is an interface diagram of another embodiment of a user interface for an order processing method according to the present invention.

FIG. 6 is a signal flow diagram illustrating the execution of another embodiment of the order processing method of the present invention.

FIG. 7 is a functional block diagram of an embodiment of an order processing apparatus according to the present invention.

Fig. 8 is a schematic internal structure diagram of an embodiment of the electronic device of the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

The invention provides an order processing method, a cloud system, electronic equipment and a storage medium.

FIG. 1 is a flow chart illustrating an embodiment of an order processing method according to the present invention; an order processing method of the present invention may be embodied as steps S10-S30 as described below.

Step S10, the client receives the order policy and execution priority related to the order set by the user.

In the embodiment of the invention, before the order processing method is executed, the client and the cloud system need to be in system docking. In a specific application scenario, the client may be implemented by a single group SDK system, or the client may run in the single group SDK system. Wherein the SDK may be understood as: software Development Kit, a Software Development Kit, is a collection of Development tools that some Software engineers typically build for a particular Software package, Software framework, hardware platform, operating system, etc. when building application Software. And the form-organizing SDK system can also perform data interaction with the cloud system by using an Application Programming Interface (API).

The user can set a corresponding processing strategy and a processing priority for the order to be processed based on the client. In one embodiment, the client may provide a user operation interface for a user to design, and based on the user operation interface, the client receives order grouping policies of different dimensions related to orders and corresponding execution priorities set by the user.

And step S20, dividing the order into a plurality of order sets with execution priority according to the set order grouping strategy and execution priority.

Step S30, the client sends the order set including the execution priority to a cloud system, so that the cloud system sends a corresponding execution command to a corresponding execution terminal.

The client divides the orders into a plurality of order sets according to the order grouping strategy set by the user; setting an execution priority order for the divided order sets according to the set execution priority, sending the order sets with the execution priority to a cloud system so that the cloud system can generate corresponding execution commands, and sending the execution commands to an execution terminal. Wherein, the execution terminal includes but is not limited to: a terminal PDA, a plurality of robots, other executable devices, and command processing devices that can assist the smart device in executing commands, etc.

Further, in an embodiment, after step S30 of the embodiment shown in fig. 1, that is, after the client sends the order set including the execution priority to a cloud system, the cloud system receives the order set including the execution priority, and always converts the order set with the highest execution priority into a plurality of command sets that can be executed according to the execution priority corresponding to the order set; and the cloud system sequentially issues the command sets to corresponding execution terminals. In the embodiment of the invention, the client only sends the order set containing the execution priority to the cloud system, the cloud system generates the corresponding command to be executed according to the order set containing the execution priority to obtain the corresponding command set, and then the command set is sent to the corresponding execution terminal. In the embodiment of the present invention, the multiple executable command sets converted by the cloud system include: a set of commands that can be executed by any smart device; wherein the smart device executing the set of commands includes, but is not limited to: intelligent terminals including robots and smart phones, intelligent execution devices, and the like, and wearable devices such as smart watches, terminal PDAs, and the like.

Further, in an embodiment, in step S30 in the embodiment of fig. 1, when the client sends the order set including the execution priority to a cloud system, the client converts the order set into a command set according to the execution priority corresponding to the order set, and then the client directly sends the corresponding command set to the cloud system.

Namely, the client side converts the order set containing the execution priority into a plurality of command sets which can be executed all the time according to the execution priority, and sends the command sets to the cloud system, so that the cloud system can issue the command sets to corresponding execution terminals in sequence.

Further, in an embodiment, the cloud system sequentially issues the command sets to an execution terminal, and then further includes: and the cloud system receives an execution result fed back by the execution terminal executing the corresponding operation according to the command set, and feeds back the execution result corresponding to the execution terminal to the client. That is to say, the execution terminal has an execution result feedback function, and the execution terminal feeds back a corresponding execution result to the cloud system while executing a corresponding command; and the cloud system synchronously feeds back the received execution result to the client so that a user can know the execution condition of the order in time based on the client, and corresponding adjustment can be made in time. In the embodiment of the present invention, the execution result fed back by the execution terminal carries a corresponding execution identifier, and the execution terminal, the order information, and the like corresponding to the execution result can be obtained according to the execution identifier.

As shown in fig. 2, fig. 2 is a signal flow diagram of an implementation process of an order processing method according to an embodiment of the present invention. In the specific application scenario illustrated in fig. 2, the specific representation form of the client is a group list SDK, and the specific representation form of the execution terminal is a robot capable of executing commands. The customer warehouse management system is in butt joint with the cloud system through the form SDK, so that the aim of butt joint of the warehouse management system and the cloud control system is fulfilled. The client sets a group list strategy and an execution priority by using the group list SDK, or modifies the set group list strategy and the execution priority; and then, the client sends the order list to be processed to the cloud system through the order-combining SDK, and the order-combining SDK divides the order into a plurality of order sets with execution priority according to an order-combining strategy and execution conditions. After the cloud system receives the order sets, the order sets with the highest priority are always converted into a plurality of executable command sets according to the execution priority. The cloud system sequentially issues the command set to a plurality of robots capable of executing commands, and the robots independently complete order processing and/or complete order processing together with assistance of operators in the warehouse according to the received contents in the command set and the corresponding processing positions in the warehouse. And after the robot command set is executed, sending the corresponding execution result to the cloud system, and informing the client of the real-time processing condition of the order by the cloud system based on the client. In addition, the client can adjust different order grouping strategies in real time to generate different order sets according to actual needs, and set priorities. The order combination SDK dynamically generates a plurality of order sets and sends the order sets to the cloud system all the time according to the latest order combination strategy and strategy execution conditions; the cloud system always processes the order set according to the priority of the order set; meanwhile, the priority of the order set can be manually adjusted through the order group SDK. For example, the client may add or delete policies and execution conditions for the group list SDK as needed. And the cloud system executes the orders according to the sequence of the received orders by default aiming at the condition that the client does not specify the order-forming strategy and the execution condition. The robot serving as the execution terminal always processes the command set generated by the order set with the highest priority, and new commands acquired by the robot each time are commands which need to be executed with the highest priority after dynamic adjustment.

Further, in an embodiment, the client receives the order-related group policy and execution priority set by the user, which may be implemented as follows.

The client receives a new bill combination strategy and/or a new execution priority which are adjusted and updated by the user according to the set bill combination strategy and/or execution priority; and/or: the client responds to an order execution progress checking instruction triggered by a user and displays the execution progress of the current order for the user to check; when the user triggers the corresponding adjusting instruction, the client receives a new order forming strategy and/or a new execution priority corresponding to the order set execution sequence adjusted by the user based on the user operation interface. The new order strategy does not affect the order set of the completed orders, and orders are formed according to the new order strategy to generate a corresponding order set aiming at the orders of which the new order strategy is set and stored.

The order combining strategy can be completely designed by a user, only the order set is sent to the cloud system through the API, and the cloud system is only responsible for issuing the command set corresponding to the order set to the robot. Likewise, the user can pause and terminate execution of the order set through the API.

For example, in one embodiment, after the client and the cloud system are docked (for example, in the specific application scenario of fig. 2, after the customer warehousing management system completes docking with the group order SDK), the customer as the user may default to setting the order combination according to time. As shown in fig. 3, fig. 3 is an interface schematic diagram of an embodiment of a user operation interface in the order processing method according to the present invention. Based on the user operation interface shown in fig. 3, the client can set a corresponding group policy.

In one embodiment, the default ordering policy is performed according to a time dimension, that is, according to the order sequence time obtained from the warehouse management system of the customer. As shown in fig. 3, fig. 3 is an interface schematic diagram of an embodiment of a user operation interface in the order processing method according to the present invention. For example, in fig. 3, the time that the user can set refers to the time when the order is obtained from the client system, or the order obtained from a certain time point can be set to be executed preferentially, or the order obtained within a certain time period can be set to be executed preferentially. In a specific application scenario, the order execution sequence is executed according to the execution priority sequence corresponding to the order set, the maximum length of the list is 10 order sets in execution, and the priority policies with the same policy name may not be the same. The user can send the order list in time periods according to the set time limit strategy, and the user needs to have stronger prejudgment on the order processing.

Furthermore, the user can also increase the strategy dimension corresponding to the group list strategy according to the actual requirement; for example, the policy dimension may be increased by setting required dimension parameters, parameter acquisition interfaces, and the like in the SDK. When adding a policy dimension, the user needs to ensure that the value of the policy parameter can be queried according to the order ID, and the following information is set in the SDK, including but not limited to: parameter Chinese name, parameter English name, order corresponding parameter acquisition URL, order forming condition and the like. For the group list condition, the user may set the group list condition as: and the list is equal to, greater than or equal to, less than or equal to or in a preset range, and the like. For example, in a specific application scenario, if a user needs to process an order according to the priority of a supplier, the information in the SDK may be set as follows, with the parameter of the chinese name: a name of the supplier; the parameter English name: english name of the supplier field in the customer database; obtaining URL by the order corresponding parameters: the interface URL of the supplier data corresponding to the order can be inquired; group conditions: equal to. After the setting, the supplier preference appears in the policy setting of the group list, as shown in fig. 4, fig. 4 is an interface schematic diagram of another embodiment of the user operation interface in the order processing method of the present invention. For example, when the group order policy set by the user is the supplier name "XXX", the corresponding order set is processed preferentially. In a specific application scenario, the group policy setting of a user can set parameters corresponding to 5 dimensions at the same time; after the user completes the setting of the order combination strategy, the total number of orders displayed by the order execution list should be 0, the completion number is 0, and the completion percentage is "-". After the user sets the corresponding order combination strategy, as shown in fig. 2, the self-owned warehousing management system is used for sending orders to the cloud system through the order combination SDK, the order combination SDK classifies and combines the orders according to the information obtained from the orders and the order combination strategy set by the user, then the order combination SDK sends a plurality of order sets which are combined completely to the cloud system, and the execution priority of each order set is marked according to the execution priority condition set by the user in the SDK. And after receiving the order sets, the cloud system always generates an order set generation command set with the highest priority according to the execution priority of the order sets and sends the order set generation command set to the robot for execution. For example, in a specific application scenario, the user needs to process 100 picking orders, and the user sets the policy "wherein 15 orders of the a supplier need to be processed first, 35 orders of the B supplier are processed after the order of the a is processed, and the remaining 50 orders are processed last. "100 orders sent by the user to the cloud system via the order-forming SDK are divided into three order sets: the highest priority P0 set contains only 15 orders for A suppliers, the P1 priority set contains only 35 orders for B suppliers, and the P2 priority set contains the other 50 orders. The cloud system processes the order sets according to the execution priority sequence of P0, P1 and P2, firstly, 15 orders with the priority P0 are combined into an order set, and then the order sets corresponding to the priorities P1 and P2 are executed in sequence.

Further, in one embodiment, after generating the corresponding order set based on the set group order policy, the user may check the execution progress of the order through the client, such as the group order SDK. The order set order execution order may also be adjusted as needed. The client sends the order set containing the execution priority to a cloud system, and the method comprises the following steps: and the client sends the adjusted and updated order set containing the new execution priority to a cloud system so that the cloud system sequentially issues new command sets to the execution terminal based on the new execution priority.

The client receives a user command which is sent by a user and used for pausing or stopping the executing order set, and sends the pause command or the stop command to the cloud system, so that the cloud system pauses or stops the executing of the order set; after the corresponding order set is suspended according to the suspension command, aiming at the orders which are executed, the execution command corresponding to the orders which are executed after suspension is not influenced, but the cloud system can not send a new command corresponding to the current order set to the execution terminal any more, and can sequentially start to process the order set with the next priority until the current order set restarts execution; after the corresponding order set is terminated according to the termination command, aiming at the orders which are executed, the execution command corresponding to the orders which are executed after termination is not influenced, but the execution command corresponding to the orders which are not executed yet is not issued to the execution terminal for execution; and aiming at the terminated order, the cloud system marks the order as unprocessed and sends notification information corresponding to the unprocessed order to the client, and when the order terminated by re-pushing of the client is received, the cloud system can issue the order terminated before the execution of the execution terminal again. As shown in fig. 5, fig. 5 is an interface schematic diagram of another embodiment of a user operation interface in the order processing method according to the present invention. And the client receives a priority adjustment instruction triggered by a user and adjusts the execution priority of the order execution list.

In a specific application scenario, a user may adjust the set group order policy in the group order SDK. After the order combination strategy is adjusted and stored, the order sent to the cloud system through the order combination SDK again generates a new order list according to the new strategy, but the order collection of the finished order combination is not influenced. As shown in fig. 6, fig. 6 is a signal flow diagram of the execution process of another embodiment of the order processing method of the present invention. If the user needs to operate on the generated order set, the executing order set can be suspended or terminated through the order-grouping SDK. After the pause, the command corresponding to the executed order is not affected, but a new command corresponding to the current order set is not sent to the robot any more, and the processing of the order set with the next priority is started in sequence until the current order set is restarted to be executed. After the execution of the order set is terminated, the command corresponding to the executed order is not affected, but the command corresponding to the order which is not executed is not issued to the robot for execution. The terminated orders are marked as unprocessed by the cloud system and are notified to the warehousing management system of the user, and the orders can be issued to the robot again to be executed after being pushed again by the user. The user can adjust the command set sent by the cloud system to the robot by adjusting the order set sent to the cloud system. For example, for order sets corresponding to the execution priority order P0> P1> P2, when the user adjusts the execution priority of a certain order set P1 to P0, the originally unexecuted P0 set is suspended and the execution priority is adjusted to P1; if the user adjusts the execution priority of a certain order set with P0 level to P1, the execution priority of the original order set with P1 execution priority is adjusted to P0, and the order set is preferentially converted to a command set and issued to the robot for execution.

In the embodiment of the order processing method, the user can dynamically adjust the order combination strategy and the corresponding execution priority of each order in real time in the whole order execution process. And enabling the order sets received by the cloud system to have a priority execution sequence through an order combination strategy. The command set issued by the cloud system to the robot for execution is always related to the order processing sequence required by the user. And generating a corresponding executable command set of the execution terminal according to the execution priority of the order set, and dynamically adjusting the processing process of the whole order by adjusting the priority of the order set, so that the method is more suitable for the personalized requirements and the temporary requirements of the user. The user can also set the order SDK according to the personalized requirements of the user, so that the personalized requirements of the user on order processing are met, the bottom logic of the cloud system on order set processing is not affected, and the processing logic of the cloud system for converting the order set into the command set is not affected, that is, the command set corresponding to the order set issued by the cloud system to the execution terminal, such as a robot, is always maintained to execute the execution policy of the order set with the highest execution priority.

The order processing method of the invention receives the order-combining strategy and the execution priority which are set by the user and are related to the order through the client; dividing the orders into a plurality of order sets with execution priorities according to the set order grouping strategy and the execution priorities; the client sends the order set containing the execution priority to a cloud system so that the cloud system can send corresponding execution commands to corresponding execution terminals; the order execution can be flexibly processed according to the user requirements, and the flexibility and the intelligence of order processing are improved; for the user side, the interactive experience of the user is improved.

Corresponding to the order processing method described in the above embodiment, the present invention also provides an order processing apparatus; the order processing apparatus can implement an order processing method described in the above embodiments. The embodiment of the present invention describes the order processing apparatus only in terms of functions. Fig. 7 is a functional module diagram of an embodiment of the order processing apparatus according to the present invention, as shown in fig. 7. The order processing apparatus shown in fig. 7 functionally includes: a setting module 100, a processing module 200 and a sending down module 300.

In one embodiment, the setting module 100 is configured to receive a group order policy and an execution priority set by a user and related to an order; the processing module 200 is configured to divide the orders into a plurality of order sets with execution priorities according to the set order grouping policy and the execution priority; the issuing module 300 is configured to send the order set including the execution priority to a cloud system, so that the cloud system sends a corresponding execution command to a corresponding execution terminal.

The order processing apparatus of the present invention executes a specific implementation manner of the corresponding order processing operation according to the order processing method, which can refer to the description of the related embodiments of the order processing method and is not described herein again.

The order processing device receives an order-forming strategy and an execution priority which are set by a user and are related to an order through a client; dividing the orders into a plurality of order sets with execution priorities according to the set order grouping strategy and the execution priorities; the client sends the order set containing the execution priority to a cloud system so that the cloud system can send corresponding execution commands to corresponding execution terminals; the order execution can be flexibly processed according to the user requirements, and the flexibility and the intelligence of order processing are improved; for the user side, the interactive experience of the user is improved.

Corresponding to the order processing method and the order processing apparatus provided in the above embodiments, the present invention further provides an electronic device, which can flexibly process a corresponding order according to the order processing method described in fig. 1. Fig. 8 is a schematic diagram of the internal structure of an embodiment of the electronic device of the present invention, as shown in fig. 8.

In the present embodiment, the electronic device 1 may be a PC (Personal Computer), or may be a terminal device such as a smartphone, a tablet Computer, or a mobile Computer. The electronic device 1 comprises at least a memory 11, a processor 12, a communication bus 13, and a network interface 14.

The memory 11 includes at least one type of readable storage medium, which includes a flash memory, a hard disk, a multimedia card, a card type memory (e.g., SD or DX memory, etc.), a magnetic memory, a magnetic disk, an optical disk, and the like. The memory 11 may in some embodiments be an internal storage unit of the electronic device 1, for example a hard disk of the electronic device 1. The memory 11 may also be an external storage device of the electronic device 1 in other embodiments, such as a plug-in hard disk provided on the electronic device 1, a Smart Media Card (SMC), a Secure Digital (SD) Card, a Flash memory Card (Flash Card), and the like. Further, the memory 11 may also include both an internal storage unit and an external storage device of the electronic device 1. The memory 11 may be used not only to store application software installed in the electronic apparatus 1 and various types of data, such as codes of the order processing program 01, but also to temporarily store data that has been output or is to be output.

Processor 12, which in some embodiments may be a Central Processing Unit (CPU), controller, microcontroller, microprocessor or other data Processing chip, executes program code or processes data stored in memory 11, such as executing order handler 01.

The communication bus 13 is used to realize connection communication between these components.

The network interface 14 may optionally include a standard wired interface, a wireless interface (e.g., WI-FI interface), and is typically used to establish a communication link between the electronic device 1 and other electronic devices.

Optionally, the electronic device 1 may further comprise a user interface, the user interface may comprise a Display (Display), an input unit such as a Keyboard (Keyboard), and the optional user interface may further comprise a standard wired interface, a wireless interface. Alternatively, in some embodiments, the display may be an LED display, a liquid crystal display, a touch-sensitive liquid crystal display, an OLED (Organic Light-Emitting Diode) touch device, or the like. The display, which may also be referred to as a display screen or display unit, is suitable for displaying information processed in the electronic device 1 and for displaying a visualized user interface, among other things.

Fig. 8 shows only the electronic device 1 with the components 11-14 and the order processing program 01, and it will be understood by those skilled in the art that the structure shown in fig. 8 does not constitute a limitation of the electronic device 1, and may comprise fewer or more components than shown, or some components may be combined, or a different arrangement of components.

Based on the description of the above embodiment, in the embodiment of the electronic device 1 shown in fig. 8, the order processing program 01 is stored in the memory 11; the order processing program 01 stored in the memory 11 is executable on the processor 12, and when the order processing program 01 is executed by the processor 12, the following steps are implemented: receiving a group order strategy and execution priority which are set by a user and are related to an order; dividing the orders into a plurality of order sets with execution priorities according to the set order grouping strategy and the execution priorities; and sending the order set containing the execution priority to a cloud system so that the cloud system can send a corresponding execution command to a corresponding execution terminal.

The electronic equipment receives the order-forming strategy and the execution priority which are set by a user and are related to the order form through the client; dividing the orders into a plurality of order sets with execution priorities according to the set order grouping strategy and the execution priorities; the client sends the order set containing the execution priority to a cloud system so that the cloud system can send corresponding execution commands to corresponding execution terminals; the order execution can be flexibly processed according to the user requirements, and the flexibility and the intelligence of order processing are improved; for the user side, the interactive experience of the user is improved.

Corresponding to the order processing method, the order processing device and the electronic equipment provided by the embodiment, the invention also provides a cloud system, wherein the cloud system can perform data interaction with the order processing device and execute order processing operation; wherein the cloud system is configured to: receiving an order set which is sent by the order processing device and contains the execution priority, and always converting the order set with the highest execution priority into a plurality of executable command sets according to the execution priority corresponding to the order set; the command sets are sequentially issued to corresponding execution terminals; wherein the execution terminal includes: a terminal PDA and/or a plurality of robots and/or other executable devices that can execute commands and/or command processing devices that can assist the smart device in executing the nomenclature.

The cloud system performs data interaction with the client, the order processing device, and the like, and executes a specific implementation manner of the corresponding order processing method, which can refer to the description of the relevant embodiments of the order processing method, the order processing device, and the electronic device, and is not described herein again.

Claims (9)

1. An order processing method, characterized in that the order processing method comprises:

the client receives a group order strategy and an execution priority which are set by a user and are related to the order; dividing the orders into a plurality of order sets with execution priorities according to the set order grouping strategy and the execution priorities; the client sends the order set containing the execution priority to a cloud system so that the cloud system can send corresponding execution commands to corresponding execution terminals;

the client receives a user command which is sent by a user and used for pausing or stopping the executing order set, and sends a pause command or a stop command to the cloud system, so that the cloud system pauses or stops the executing of the order set; after the corresponding order set is suspended according to the suspension command, aiming at the orders which are executed, the execution command corresponding to the orders which are executed after suspension is not influenced, but the cloud system can not send a new command corresponding to the current order set to the execution terminal any more, and can sequentially start to process the order set with the next priority until the current order set restarts execution; after the corresponding order set is terminated according to the termination command, aiming at the orders which are executed, the execution command corresponding to the orders which are executed after termination is not influenced, but the execution command corresponding to the orders which are not executed yet is not issued to the execution terminal for execution; aiming at the terminated order, the cloud system is marked as unprocessed and sends notification information corresponding to the unprocessed order to the client, and when the terminated order pushed again by the client is received, the cloud system can issue the order which is terminated before the execution of the execution terminal again;

the method for receiving the order-group policy and the execution priority related to the order set by the user by the client comprises the following steps: the client provides a user operation interface for a user to design, and receives order grouping strategies with different dimensions related to orders and corresponding execution priorities, which are set by the user, on the basis of the user operation interface; the client receives a new bill combination strategy and/or a new execution priority which are adjusted and updated by the user according to the set bill combination strategy and/or execution priority; the client responds to an order execution progress checking instruction triggered by a user and displays the execution progress of the current order for the user to check; receiving a new order combination strategy and/or a new execution priority corresponding to the order combination execution sequence adjusted by the user based on the user operation interface; the new order strategy does not affect the order set of the completed orders, and orders are formed according to the new order strategy to generate a corresponding order set aiming at the orders of which the new order strategy is set and stored.

2. The order processing method of claim 1, wherein the client sends the order set including the execution priority to a cloud system, and then further comprising:

the cloud end system receives an order set containing the execution priority, and always converts the order set with the highest execution priority into a plurality of executable command sets according to the execution priority corresponding to the order set;

the cloud system sequentially issues the command sets to corresponding execution terminals; wherein the execution terminal includes: a terminal PDA and/or a plurality of robots and/or other executable devices that can execute commands and/or command processing devices that can assist the smart device in executing the nomenclature.

3. The order processing method of claim 1, wherein the client sends the order set including the execution priority to a cloud system, comprising:

and the client side converts the order set containing the execution priority into a plurality of command sets which can be executed all the time according to the execution priority, and sends the command sets to a cloud system, so that the cloud system can issue the command sets to corresponding execution terminals in sequence.

4. The order processing method of claim 2 or 3, wherein the cloud system issues the command sets to corresponding execution terminals in sequence, and then further comprises:

and the cloud system receives an execution result fed back by the execution terminal executing the corresponding operation according to the command set, and feeds back the execution result corresponding to the execution terminal to the client.

5. The order processing method of claim 1, 2 or 3, wherein the client sends the order set including the execution priority to a cloud system, comprising:

and the client sends the adjusted and updated order set containing the new execution priority to a cloud system so that the cloud system sequentially issues new command sets to corresponding execution terminals based on the new execution priority.

6. An order processing apparatus, characterized in that the order processing apparatus comprises:

the setting module is used for receiving order-combining strategies and execution priorities which are set by a user and are related to orders;

the processing module is used for dividing the orders into a plurality of order sets with execution priorities according to the set order grouping strategy and the execution priorities;

the issuing module is used for sending the order set containing the execution priority to a cloud system so that the cloud system can send a corresponding execution command to a corresponding execution terminal;

receiving a user command which is sent by a user and used for suspending or stopping the order set being executed, and sending the suspending command or the stopping command to the cloud end system so that the cloud end system can suspend or stop the execution of the order set; after the corresponding order set is suspended according to the suspension command, aiming at the orders which are executed, the execution command corresponding to the orders which are executed after suspension is not influenced, but the cloud system can not send a new command corresponding to the current order set to the execution terminal any more, and can sequentially start to process the order set with the next priority until the current order set restarts execution; after the corresponding order set is terminated according to the termination command, aiming at the orders which are executed, the execution command corresponding to the orders which are executed after termination is not influenced, but the execution command corresponding to the orders which are not executed yet is not issued to the execution terminal for execution; aiming at the terminated order, the cloud system is marked as unprocessed and sends notification information corresponding to the unprocessed order to the client, and when the terminated order pushed again by the client is received, the cloud system can issue the order which is terminated before the execution of the execution terminal again;

wherein the setting module is configured to: providing a user operation interface for a user to design, and receiving order grouping strategies with different dimensions related to orders and corresponding execution priorities, which are set by the user, based on the user operation interface; receiving a new bill-of-things policy and/or a new execution priority updated by a user to adjust the set bill-of-things policy and/or the set execution priority; responding to an order execution progress checking instruction triggered by a user, and displaying the execution progress of the current order for the user to check; receiving a new order combination strategy and/or a new execution priority corresponding to the order combination execution sequence adjusted by the user based on the user operation interface; the new order strategy does not affect the order set of the completed orders, and orders are formed according to the new order strategy to generate a corresponding order set aiming at the orders of which the new order strategy is set and stored.

7. The cloud system is characterized in that the cloud system can perform data interaction with an order processing device and execute order processing operation; wherein the cloud system is configured to:

receiving an order set which is sent by the order processing device and contains execution priority, and always converting the order set with the highest execution priority into a plurality of executable command sets according to the execution priority corresponding to the order set;

the command sets are sequentially issued to corresponding execution terminals; wherein the execution terminal includes: the terminal PDA and/or a plurality of robots capable of executing commands and/or other executable devices and/or command processing devices capable of assisting the intelligent device to execute the naming;

wherein the order set is: the order processing device receives an order-combining strategy and an execution priority which are set by a user and are related to orders; dividing orders into order sets with execution priorities according to the set order grouping strategy and the execution priorities;

the order processing device receives order-combining strategies and execution priorities related to orders, which are set by a user, and comprises the following steps: providing a user operation interface for a user to design, and receiving order grouping strategies with different dimensions related to orders and corresponding execution priorities, which are set by the user, based on the user operation interface; receiving a new bill-of-things policy and/or a new execution priority updated by a user to adjust the set bill-of-things policy and/or the set execution priority; responding to an order execution progress checking instruction triggered by a user, and displaying the execution progress of the current order for the user to check; receiving a new order combination strategy and/or a new execution priority corresponding to the order combination execution sequence adjusted by the user based on the user operation interface; the new order strategy does not influence the order set of the completed orders, and orders are formed according to the new order strategy to generate a corresponding order set aiming at the orders of which the new order strategy is set and stored;

the cloud system is further configured to: receiving a pause command or a termination command for pausing or terminating an executing order set, and pausing or terminating the execution of the order set; after the corresponding order set is suspended according to the suspension command, aiming at the orders which are executed, the execution command corresponding to the orders which are executed after suspension is not influenced, but the cloud system can not send a new command corresponding to the current order set to the execution terminal any more, and can sequentially start to process the order set with the next priority until the current order set restarts execution; after the corresponding order set is terminated according to the termination command, aiming at the orders which are executed, the execution command corresponding to the orders which are executed after termination is not influenced, but the execution command corresponding to the orders which are not executed yet is not issued to the execution terminal for execution; and aiming at the terminated order, the cloud system marks the order as unprocessed and sends notification information corresponding to the unprocessed order to the client, and when the order terminated by re-pushing of the client is received, the cloud system can issue the order terminated before the execution of the execution terminal again.

8. An electronic device, comprising a memory and a processor, wherein the memory has stored thereon an order processing program executable on the processor, and wherein the order processing program, when executed by the processor, performs the order processing method according to any one of claims 1 to 5.

9. A computer readable storage medium having stored thereon an order processing program executable by one or more processors to implement the steps of the order processing method of any one of claims 1 to 5.

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