CN112541709A - Intelligent warehouse management and allocation system and management and allocation method thereof - Google Patents

Abstract

The invention discloses an intelligent warehouse management allocation system, belonging to the field of intelligent warehouse management allocation; in particular to an intelligent warehouse management allocation system and a management allocation method thereof; the invention sends out control instructions through the system framework unit, and can reasonably distribute task instructions according to the working condition and the task quantity of the working equipment at the moment; meanwhile, the management allocation unit receives the control instruction through the communication mode unit and sends an execution instruction according to the control instruction; carrying out reasonable driving of working equipment, monitoring of the working equipment and path optimization of various equipment through the received task allocation instruction, and finally receiving the execution instruction by the execution architecture unit and carrying out work execution; a plurality of different devices can work simultaneously; the invention realizes multi-thread transmission through various communication modes, thereby effectively ensuring smooth communication and multi-task communication and enhancing the working efficiency.

Description

Intelligent warehouse management and allocation system and management and allocation method thereof

Technical Field

The invention discloses an intelligent warehouse management allocation system, belonging to the field of intelligent warehouse management allocation; in particular to an intelligent warehouse management allocation system and a management allocation method thereof.

Background

Warehousing serves as a very critical and important link in modern logistics and plays a role in taking over the upstream and downstream positions of a supply chain. With the rapid development of economic technology, the traditional storage technology is no longer suitable for the development of modern logistics technology, and the problems of bin explosion and shortage are connected in series. With the popularization of the internet of things technology, the internet of things technology provides a chance for the storage development to break through the bottleneck. The proposal and the development of the intelligent warehousing management system enable the development of warehousing to have larger research space.

With the shortage of land resources and the rapid rise of labor cost, the development of the warehouse logistics industry faces serious restrictions, so that an automatic intelligent warehouse system suitable for multiple robots and multiple targets is designed, the enterprise is transformed from automation to full intelligence, and the system becomes a research hotspot.

With the development of market economy and the arrival of the information era, the common warehousing management allocation system can not meet the existing requirements of work material allocation, especially the allocation when the shortage of materials occurs can not achieve reasonable allocation, and when various working devices work simultaneously, the warehousing management allocation system can not carry out scheduling and task allocation simultaneously and can not provide route optimization for the working devices under the multi-task working condition.

Disclosure of Invention

The purpose of the invention is as follows: an intelligent warehouse management and allocation system and a management and allocation method thereof are provided to solve the above problems.

The technical scheme is as follows: an intelligent warehouse management deployment system, comprising:

the system framework unit is used for sending a control instruction and reasonably distributing task instructions according to the working condition and the task quantity of the working equipment at the moment;

the management allocation unit is used for receiving the control instruction and sending out an execution instruction according to the control instruction; reasonably driving the working equipment, monitoring the working equipment and optimizing paths of various equipment through the received task allocation instructions;

the communication mode unit is used for transmitting the control instruction sent by the system framework unit to the management allocation unit; multithread transmission is realized through various communication modes, so that smooth communication and multitask communication can be effectively guaranteed;

the execution architecture unit is used for receiving the execution instruction and executing work execution; can carry out the simultaneous working of multiple different equipment, reinforcing work efficiency.

Preferably, the management deployment unit includes:

the client module is used for carrying out a program for providing local service and mainly finishing the work task of the client;

the warehousing control module is used for outputting warehousing equipment execution commands according to the control instructions sent by the system framework unit; the method is distributed to different working devices according to different working instructions, so that task congestion and task disorder can be prevented;

the data control module is used for accessing and managing the warehousing data; the data storage and the data access are separated, so that the data access monitoring and the data storage can be carried out simultaneously.

Preferably, the warehousing control module comprises:

the communication control submodule is used for receiving the communication signal and controlling the communication equipment;

the service control submodule is used for receiving the equipment management signal and carrying out control management on the working equipment;

and the service control submodule is used for receiving the equipment state signal and sending the state information.

Preferably, the data control module includes:

the access interface submodule is used for establishing connection between the system and equipment needing to be accessed and transmitting signals;

and the storage submodule is used for storing and managing system data.

Preferably, the management deployment unit further comprises:

and the interface module is used for establishing connection with an enterprise management system, a logistics attraction system and other systems of the intelligent warehouse.

Preferably, the interface module includes:

the network interface submodule is used for managing and allocating the connection between the system and the Internet through a TCP (transmission control protocol) and an I9 protocol;

the host interface sub-module is used for connecting the host program with other host programs through an SOCKET protocol;

the industrial interface submodule is used for managing and allocating the connection between the working equipment and other equipment through an OPC protocol;

and the serial port interface submodule is used for managing and allocating the receiving signals and the output signals of the system through a serial port communication protocol.

Preferably, the system architecture unit includes:

the client layer module is used for sending a control instruction to the client;

the processing layer module is used for sending various instructions to the warehousing control module;

and the data layer module is used for sending various instructions to the warehousing control module.

Preferably, the processing layer module includes:

the communication layer submodule is used for receiving the communication signal sent by the processing layer module and sending the communication signal to the communication control submodule;

the service logic layer submodule is used for receiving the equipment control signal sent by the processing layer module and sending the equipment control signal to the service control submodule;

and the basic service layer submodule is used for receiving the service signal sent by the processing layer module and sending the service signal to the service control submodule.

Preferably, the data layer module includes:

the data access layer submodule is used for receiving the access signal sent by the data layer submodule and sending the access signal to the data access interface submodule;

and the data storage layer submodule is used for receiving the storage signal sent by the receipt layer module and sending the storage signal to the storage submodule.

Preferably, the communication means unit includes:

the client layer communication module is used for transmitting information instructions between the client layer module and the client layer module;

the processing layer communication module is used for transmitting information instructions between the processing layer module and the warehousing control module;

the data layer communication module is used for transmitting information instructions between the data layer module and the data control module;

wherein the first communication module comprises:

the first communication module is used for transmitting signal information instructions between the communication layer submodule and the communication control submodule;

the second communication module is used for transmitting the signal information instruction between the service logic layer submodule and the service control submodule;

and the third communication module is used for transmitting the signal information instruction between the basic service layer submodule and the service control submodule.

Preferably, the execution architecture unit includes:

the client execution architecture module is used for executing an information control instruction sent by the client;

the processing layer execution architecture module is used for executing the information control instruction sent by the processing layer;

and the data layer execution architecture module is used for executing the information control instruction sent by the data layer.

An intelligent warehouse management allocation system and a management allocation method thereof comprise:

the client layer module in the system framework unit sends out connection and establishes connection with the client module;

the client executing architecture unit drives the PC to work;

a processing layer module in the system framework unit outputs a control instruction to a communication layer submodule, a business logic layer submodule and a basic service layer submodule;

the communication layer submodule receives a control instruction sent by the processing layer module;

the first communication module establishes a communication layer submodule to be connected with the communication control submodule;

the communication layer submodule outputs a control instruction to the communication control submodule through the first communication module;

the business logic layer submodule receives a control instruction sent by the processing layer module;

the second communication module establishes the connection between the service logic layer submodule and the service control submodule;

the service logic layer submodule outputs a control instruction to the service control submodule through the second communication module;

the basic service layer submodule receives a control instruction sent by the processing layer module;

the third communication module establishes connection between the basic service layer submodule and the basic service layer submodule;

the basic service layer submodule outputs a control instruction through a third communication module;

the processing layer executes the architecture module to perform warehousing management and allocation work.

Preferably, when the warehousing management allocation work is carried out each time, the data layer module records the start time and the end time of the work, various information parameters of the working equipment and various types, so as to store the information; the method comprises the following steps:

the data access layer submodule receives an access instruction sent by the data layer module;

the data access layer submodule is connected with the access interface submodule;

the access interface sub-module receives the access instruction and outputs an access signal to the data layer execution architecture module;

the data layer execution architecture module drives various devices to complete access work;

the data storage layer submodule receives a storage instruction sent by the data layer module;

the access interface submodule and the storage submodule receive a storage instruction and output a storage signal to the data layer execution architecture module;

the data layer execution architecture module drives various devices to complete storage work.

Has the advantages that: the invention sends out control instructions through the system framework unit, and can reasonably distribute task instructions according to the working condition and the task quantity of the working equipment at the moment; meanwhile, the management allocation unit receives the control instruction through the communication mode unit and sends an execution instruction according to the control instruction; carrying out reasonable driving of working equipment, monitoring of the working equipment and path optimization of various equipment through the received task allocation instruction, and finally receiving the execution instruction by the execution architecture unit and carrying out work execution; a plurality of different devices can work simultaneously; the invention realizes multi-thread transmission through various communication modes, thereby effectively ensuring smooth communication and multi-task communication and enhancing the working efficiency.

Drawings

FIG. 1 is a system block diagram of the present invention.

Fig. 2 is a diagram of the operation type of the service control sub-module of the present invention.

Fig. 3 is a working diagram of the management deployment method of the present invention.

FIG. 4 is a process level working diagram of the present invention.

FIG. 5 is a data layer partial working diagram of the present invention.

FIG. 6 is a data layer partial working diagram of the present invention.

Detailed Description

In this embodiment, an intelligent warehousing management deployment system and a management deployment method thereof include: system architecture unit, management allocation unit, communication mode unit, and execution architecture unit.

In one embodiment, the system framework unit is used for sending a control command, and can reasonably distribute task commands according to the working condition and the number of tasks of the working equipment at the moment.

In one embodiment, the management deployment unit is configured to receive the control command and issue an execution command according to the control command; and reasonably driving the working equipment, monitoring the working equipment and optimizing paths of various equipment through the received task allocation instructions.

In one embodiment, the communication means unit is configured to transmit a control command issued by the system architecture unit to the management deployment unit; multithread transmission is realized through various communication modes, so that smooth communication and multitask communication can be effectively guaranteed.

In one embodiment, the execution architecture unit is used for receiving the execution instruction and executing work execution; can carry out the simultaneous working of multiple different equipment, reinforcing work efficiency.

In one embodiment, managing the deployment unit comprises: the system comprises a client module, a storage control module and a data control module.

In one embodiment, the client module is used for executing a program for providing local services, and mainly completes the work task of the client.

In one embodiment, the warehousing control module is used for outputting warehousing equipment execution commands according to control instructions sent by the system framework unit; the work orders are distributed to different work devices according to different work orders, so that task congestion and task disorder can be prevented.

In one embodiment, the data control module is used for accessing and managing the warehousing data; the data storage and the data access are separated, so that the data access monitoring and the data storage can be carried out simultaneously.

In one embodiment, the warehousing control module comprises: a communication control sub-module, a business control sub-module and a service control sub-module.

In one embodiment, the communication control sub-module is used for receiving communication signals and controlling the communication equipment.

In one embodiment, the service control submodule is used for receiving the device management signal and performing control management on the working device.

In one embodiment, the service control sub-module is used for receiving the equipment status signal and sending the status information.

In one embodiment, the data control module includes: an access interface submodule and a storage submodule.

In one embodiment, the access interface submodule is used for establishing connection between the system and the equipment needing to be accessed and transmitting signals.

In one embodiment, the storage submodule is used for storing and managing system data.

In one embodiment, the managing deployment unit further comprises: and an interface module.

In one embodiment, the interface module is used for establishing connection with an enterprise management system, a logistics attraction and other systems of the intelligent warehouse.

In one embodiment, the interface module comprises: the system comprises a network interface sub-module, a host interface sub-module, an industrial interface sub-module and a serial interface sub-module.

In one embodiment, the network interface sub-module is used for managing and allocating the connection of the system and the internet through a TCP protocol and an I9 protocol.

In one embodiment, the host interface sub-module is used for connecting the host program with other host programs through a SOCKET protocol.

In one embodiment, the industrial interface submodule is used for managing and allocating the connection between the working equipment and other equipment through an OPC protocol.

In one embodiment, the serial interface submodule is configured to manage a receiving signal and an output signal of the deployment system through a serial communication protocol.

In one embodiment, a system architecture unit comprises: the system comprises a client layer module, a processing layer module and a data layer module.

In one embodiment, the client layer module is used for sending a control instruction to the client.

In one embodiment, the processing layer module is used for sending various instructions to the warehousing control module.

In one embodiment, the data layer module is used for sending various instructions to the warehousing control module.

In one embodiment, the processing layer module comprises: the system comprises a communication layer submodule, a business logic layer submodule and a basic service layer submodule.

In one embodiment, the communication layer sub-module is configured to receive the communication signal sent by the processing layer module and send the communication signal to the communication control sub-module.

In one embodiment, the service logic layer submodule is configured to receive the device control signal sent by the processing layer module and send the device control signal to the service control submodule.

In one embodiment, the basic service layer submodule is configured to receive a service signal sent by the processing layer module and send the service signal to the service control submodule.

In one embodiment, the data layer module comprises: a data access layer submodule and a data storage layer submodule.

In one embodiment, the data access layer submodule is configured to receive an access signal sent by the data layer module and send the access signal to the data access interface submodule.

In one embodiment, the data storage layer submodule is used for receiving a storage signal sent by the receipt layer module and sending the storage signal to the storage submodule.

In one embodiment, the communication means unit includes: the device comprises a client layer communication module, a processing layer communication module and a data layer communication module.

In one embodiment, the client layer communication module is used for information instruction transmission between the client module and the client layer module.

In one embodiment, the processing layer communication module is used for transmitting information instructions between the processing layer module and the warehousing control module.

In one embodiment, the data layer communication module is used for information instruction transmission between the data layer module and the data control module.

In one embodiment, the processing layer communication module comprises: the communication device comprises a first communication module, a second communication module and a third communication module.

In one embodiment, the first communication module is used for signal information instruction transmission between the communication layer sub-module and the communication control sub-module.

In one embodiment, the second communication module is used for signal information instruction transmission between the service logic layer sub-module and the service control sub-module.

In one embodiment, the third communication module is used for signal information instruction transmission between the basic service layer sub-module and the service control sub-module.

In one embodiment, the execution architecture unit includes: the client executes the framework module, processes the layer and executes the framework module and the data layer and executes the framework module.

In one embodiment, the client executes the architecture module to execute the information control command issued by the client.

In one embodiment, the processing layer executes the architecture module to execute the information control instruction issued by the processing layer.

In one embodiment, the data layer executes the architecture module, is used for carrying out the information control command that the data layer sends out.

In one embodiment, the communication control sub-module mainly comprises parameter analysis and session management.

In one embodiment, the service control sub-module mainly includes: the system comprises the following components of system management, task management, storage space management, equipment management, event management, map management, position management, charging management, parking management, path planning, state monitoring, task splitting, system log, AGV management, multi-pass vehicle scheduling, letter vehicle scheduling, four-item vehicle scheduling, conveying line scheduling, elevator scheduling, stacker scheduling, goods space distribution, equipment scheduling, path generation, lock management and the like.

In one embodiment, the service control sub-module essentially comprises: device heartbeat information, device task delivery, device execution exceptions, and the like.

In one embodiment, the communication mode of the processing layer communication module is mainly realized by matching a VUE framework technology, a JQGrid framework technology, a CSS programming technology and a JavaScript programming technology.

In one embodiment, the first communication module is implemented mainly by matching a Netty communication technology, a Socket communication technology, a webscene network communication technology, an XML technology, a JSON data interaction technology and a multithreading technology.

In one embodiment, the second communication module communication mode is mainly realized by matching of a Shiro security framework technology, a Serviet server technology, a Spring application framework technology, a Spring boot application framework configuration technology, a Queue data structure management technology, a multithreading technology and a storage process technology.

In one embodiment, the third communication module is implemented by mainly matching a Netty communication technology, a Socket communication technology and a pipeline technology.

In one embodiment, the data layer communication module communication mode is mainly realized by a persistent layer framework technology.

In one embodiment, the communication control sub-module and the service control sub-module are controlled by adopting a command object response technology.

In one embodiment, the service control submodule and the access interface submodule communicate by using Java object technology.

As shown in fig. 3 and 4, an intelligent warehouse management and deployment system and a management and deployment method thereof include the following steps:

s1, establishing connection between the client layer module and the client module;

s2, the client executing architecture unit drives the PC to work;

s3, the processing layer module in the system frame unit outputs control instructions to the communication layer submodule, the service logic layer submodule and the basic service layer submodule;

s310, the communication layer submodule receives a control instruction sent by the processing layer module;

s311, the first communication module establishes a communication layer submodule to be connected with a communication control submodule;

s312, the communication layer submodule outputs a control instruction to the communication control submodule through the first communication module;

s320, the service logic layer submodule receives a control instruction sent by the processing layer module;

s321, the second communication module establishes connection between the service logic layer submodule and the service control submodule;

s322, the service logic layer submodule outputs a control instruction to the service control submodule through the second communication module;

s330, the basic service layer submodule receives a control instruction sent by the processing layer module;

s331, the third communication module establishes connection between the basic service layer submodule and the basic service layer submodule;

s332, the basic service layer submodule outputs a control instruction through the third communication module;

s4, the processing layer executes the framework module to perform warehousing management and allocation work;

in one embodiment, when the warehousing management allocation work is performed each time, the data layer module records the start time and the end time of the work, various information parameters of the working equipment and various types, so as to store the information; the method comprises the following steps:

s5, the data access layer submodule receives an access instruction sent by the data layer module;

s51, the data access layer submodule is connected with the access interface submodule;

s52, the access interface sub-module receives the access instruction and outputs an access signal to the data layer execution architecture module;

s53, the data layer execution architecture module drives various devices to complete access work;

s6, the data storage layer submodule receives a storage instruction sent by the data layer module;

s61, the access interface sub-module and the storage sub-module receive the storage instruction and output a storage signal to the data layer execution architecture module;

and S62, driving various devices by the data layer execution architecture module to complete the storage work.

The working principle is as follows: the client layer module in the system framework unit sends out connection and establishes connection with the client module; the client executing architecture unit drives the PC to work; a processing layer module in the system framework unit outputs a control instruction to a communication layer submodule, a business logic layer submodule and a basic service layer submodule; the communication layer submodule receives a control instruction sent by the processing layer module; the first communication module establishes a communication layer submodule to be connected with the communication control submodule; the communication layer submodule outputs a control instruction to the communication control submodule through the first communication module; the business logic layer submodule receives a control instruction sent by the processing layer module; the second communication module establishes the connection between the service logic layer submodule and the service control submodule; the service logic layer submodule outputs a control instruction to the service control submodule through the second communication module; the basic service layer submodule receives a control instruction sent by the processing layer module; the third communication module establishes connection between the basic service layer submodule and the basic service layer submodule; the basic service layer submodule outputs a control instruction through a third communication module; the processing layer execution architecture module performs warehousing management allocation work;

when the warehousing management allocation work is carried out each time, the data layer module records the start time and the end time of the work, various information parameters of the working equipment and various types, so that the information is stored; the data access layer submodule receives an access instruction sent by the data layer module; the data access layer submodule is connected with the access interface submodule; the access interface sub-module receives the access instruction and outputs an access signal to the data layer execution architecture module; the data layer execution architecture module drives various devices to complete access work; the data storage layer submodule receives a storage instruction sent by the data layer module; the access interface submodule and the storage submodule receive a storage instruction and output a storage signal to the data layer execution architecture module; the data layer execution architecture module drives various devices to complete storage work.

It should be noted that the various features described in the above embodiments may be combined in any suitable manner without departing from the scope of the invention. The invention is not described in detail in order to avoid unnecessary repetition.

Claims (10)

1. An intelligent warehousing management deployment system, comprising:

the system framework unit is used for sending a control instruction;

the management allocation unit is used for receiving the control instruction and sending out an execution instruction according to the control instruction;

the communication mode unit is used for transmitting the control instruction sent by the system framework unit to the management allocation unit;

and the execution architecture unit is used for receiving the execution instruction and executing work execution.

2. The intelligent warehousing management deployment system of claim 1 wherein the management deployment unit comprises:

the client module is used for carrying out a program for providing local service;

the warehousing control module is used for outputting warehousing equipment execution commands according to the control instructions sent by the system framework unit;

and the data control module is used for accessing and managing the warehousing data.

3. The intelligent warehousing management deployment system of claim 2 wherein the warehousing control module comprises:

the communication control submodule is used for receiving the communication signal and controlling the communication equipment;

the service control submodule is used for receiving the equipment management signal and carrying out control management on the working equipment;

and the service control submodule is used for receiving the equipment state signal and sending the state information.

4. The intelligent warehouse management deployment system of claim 2 wherein the data control module comprises:

the access interface submodule is used for establishing connection between the system and equipment needing to be accessed and transmitting signals;

and the storage submodule is used for storing and managing system data.

5. The intelligent warehousing management deployment system of claim 1 wherein the management deployment unit further comprises:

the interface module is used for establishing connection with an enterprise management system, a logistics attraction system and other systems of the intelligent storage;

the interface module includes:

the network interface submodule is used for managing and allocating the connection between the system and the Internet through a TCP (transmission control protocol) and an I9 protocol;

the host interface sub-module is used for connecting the host program with other host programs through an SOCKET protocol;

the industrial interface submodule is used for managing and allocating the connection between the working equipment and other equipment through an OPC protocol;

and the serial port interface submodule is used for managing and allocating the receiving signals and the output signals of the system through a serial port communication protocol.

6. The intelligent warehouse management deployment system of claim 1 wherein the system frame unit comprises:

the client layer module is used for sending a control instruction to the client;

the processing layer module is used for sending various instructions to the warehousing control module;

the data layer module is used for sending various instructions to the warehousing control module;

wherein the processing layer module comprises:

the communication layer submodule is used for receiving the communication signal sent by the processing layer module and sending the communication signal to the communication control submodule;

the service logic layer submodule is used for receiving the equipment control signal sent by the processing layer module and sending the equipment control signal to the service control submodule;

the basic service layer submodule is used for receiving the service signal sent by the processing layer module and sending the service signal to the service control submodule;

the data layer module includes:

the data access layer submodule is used for receiving the access signal sent by the data layer submodule and sending the access signal to the data access interface submodule;

and the data storage layer submodule is used for receiving the storage signal sent by the receipt layer module and sending the storage signal to the storage submodule.

7. The intelligent warehousing management deployment system of claim 1 wherein the communication means unit comprises:

the client layer communication module is used for transmitting information instructions between the client layer module and the client layer module;

the processing layer communication module is used for transmitting information instructions between the processing layer module and the warehousing control module;

the data layer communication module is used for transmitting information instructions between the data layer module and the data control module;

wherein the first communication module comprises:

the first communication module is used for transmitting signal information instructions between the communication layer submodule and the communication control submodule;

the second communication module is used for transmitting the signal information instruction between the service logic layer submodule and the service control submodule;

and the third communication module is used for transmitting the signal information instruction between the basic service layer submodule and the service control submodule.

8. The intelligent warehouse management deployment system of claim 1 wherein the execution architecture unit comprises:

the client execution architecture module is used for executing an information control instruction sent by the client;

the processing layer execution architecture module is used for executing the information control instruction sent by the processing layer;

and the data layer execution architecture module is used for executing the information control instruction sent by the data layer.

9. An intelligent warehouse management deployment system and a management deployment method thereof according to any one of claims 2 to 8, comprising:

the client layer module in the system framework unit sends out connection and establishes connection with the client module;

the client executing architecture unit drives the PC to work;

a processing layer module in the system framework unit outputs a control instruction to a communication layer submodule, a business logic layer submodule and a basic service layer submodule;

the communication layer submodule receives a control instruction sent by the processing layer module;

the first communication module establishes a communication layer submodule to be connected with the communication control submodule;

the communication layer submodule outputs a control instruction to the communication control submodule through the first communication module;

the business logic layer submodule receives a control instruction sent by the processing layer module;

the second communication module establishes the connection between the service logic layer submodule and the service control submodule;

the service logic layer submodule outputs a control instruction to the service control submodule through the second communication module;

the basic service layer submodule receives a control instruction sent by the processing layer module;

the third communication module establishes connection between the basic service layer submodule and the basic service layer submodule;

the basic service layer submodule outputs a control instruction through a third communication module;

the processing layer executes the architecture module to perform warehousing management and allocation work.

10. The intelligent warehousing management deployment system and the management deployment method thereof according to claim 9, wherein the data layer module records the start time and the end time of the work and various information parameters and various types of the working equipment when the warehousing management deployment work is performed each time, so as to store the information; it is characterized by comprising:

the data access layer submodule receives an access instruction sent by the data layer module;

the data access layer submodule is connected with the access interface submodule;

the access interface sub-module receives the access instruction and outputs an access signal to the data layer execution architecture module;

the data layer execution architecture module drives various devices to complete access work;

the data storage layer submodule receives a storage instruction sent by the data layer module;

the access interface submodule and the storage submodule receive a storage instruction and output a storage signal to the data layer execution architecture module;

the data layer execution architecture module drives various devices to complete storage work.

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