CN116596448A - Service-oriented manufacturing network collaborative manufacturing construction method and system - Google Patents

Abstract

The application discloses a network collaborative manufacturing construction method and a system for service-oriented manufacturing, wherein the method comprises the following steps: acquiring production parameters and quantity of products to be produced from orders of clients; acquiring the specifications of raw materials or components required by producing the product according to the production parameters, and acquiring the number of the raw materials or components required by producing the product according to the number; acquiring a first geographical position of production equipment for producing products, and acquiring a second geographical position of a warehouse storing raw materials or components; configuring raw materials or components for producing a product from one or more warehouses nearest to the first geographic location, and generating configuration information; and sending the configuration information to a corresponding warehouse. The application solves the problems of low efficiency and influence on the production progress of the product caused by manually arranging raw materials or components in the production process of the customized product, thereby improving the rationality of the arrangement of the raw materials or the components and the production progress of the product.

Description

Service-oriented manufacturing network collaborative manufacturing construction method and system

Technical Field

The application relates to the field of intelligent manufacturing, in particular to a network collaborative manufacturing construction method and system for service-oriented manufacturing.

Background

In the conventional manufacturing industry, there are generally manufacturers that produce products and then put the produced products on the market. The production method of the product can set a standard production flow for the product to be produced, and the product is produced in large batch by using the same raw materials and production process. The production mode can reduce the cost of the product to the greatest extent.

However, this production method has its own weakness, that is, the produced product may not meet the needs of some users. The user cannot achieve customized production. To solve this problem, a concept of direct user manufacturing, i.e., C2M is an abbreviation of english Customer-to-Manufacturer, is proposed in the related art, and is a new commercial model of industrial internet e-commerce, which is also called "short-circuit economy".

In the C2M mode, the concept of consumer (also referred to as customer) direct to the factory is introduced, with emphasis on the engagement of the manufacturing industry with the consumer. In fact, it is a "smart" mode: in the C2M mode, consumers directly place orders through a platform, and factories receive personalized demand orders of the consumers and then design, purchase, production and shipment according to demands. Mainly comprises pure flexible production and small-batch and multi-batch rapid supply chain reaction.

In the related art, the raw materials or components required for producing the product are still arranged manually, and the arrangement mode has low efficiency on one hand, and cannot accurately control the raw materials or components on the other hand, so that the production progress of the product is influenced.

Disclosure of Invention

The embodiment of the application provides a network collaborative manufacturing construction method and a system for service-oriented manufacturing, which at least solve the problems of low efficiency and influence on the production progress of a product caused by manually arranging raw materials or components in the production process of a customized product.

According to one aspect of the present application, there is provided a network collaborative manufacturing construction method for service-oriented manufacturing, including: acquiring an order of a customer, and acquiring production parameters and quantity of products to be produced from the order of the customer; acquiring the specifications of raw materials or components required to be used for producing the product according to the production parameters, and acquiring the number of the raw materials or components required to be used for producing the product according to the number; acquiring a first geographical location of a production facility for producing the product and acquiring a second geographical location of a warehouse storing the raw materials or components; configuring raw materials or components for producing the product from one or more warehouses nearest to the first geographic position according to the first geographic position, the second geographic position and the number of the raw materials or components, and generating configuration information, wherein the configuration information is used for indicating warehouses for preparing the raw materials or the components and preparing the specifications and the number of the raw materials or the components from each warehouse; and sending the configuration information to a corresponding warehouse.

Further, after sending the configuration information to the corresponding warehouse, the method further comprises: after the warehouse which receives the configuration information successfully transmits the raw materials or the components to a first geographical position where the production equipment is located according to the configuration information, acquiring the cost and time consumed by transmitting the raw materials or the components; the cost and time are saved in a database.

Further, configuring raw materials or components for producing the product from one or more warehouses nearest to the first geographic location according to the first geographic location, the second geographic location, and the number of raw materials or components comprises: acquiring the cost and time corresponding to the order with the maximum similarity of the raw materials or components from the database under the condition that a plurality of warehouses closest to the first geographic position are provided; and selecting a warehouse with optimal cost and time as a warehouse for sending raw materials or components of the product to the production equipment.

Further, selecting a warehouse that is optimal in terms of cost and time as a warehouse that transmits raw materials or components of the product to the production facility includes: acquiring the corresponding cost and time of each warehouse, configuring the maximum cost of each warehouse as 1, and configuring the longest time in each warehouse as 1; taking the ratio of other costs to the maximum cost as a first value of the cost, and taking the ratio of other times to the maximum time as a second value of the time; taking a weighted sum of a first numerical value and a second numerical value of each warehouse as an evaluation value of the warehouse, wherein the weights of the first numerical value and the second numerical value are preconfigured; and selecting the warehouse with the minimum evaluation value as the warehouse with the optimal cost and time.

According to another aspect of the present application, there is also provided a network collaborative manufacturing construction system for service-oriented manufacturing, including: the first acquisition module is used for acquiring orders of clients and acquiring production parameters and quantity of products to be produced from the orders of the clients; the second acquisition module is used for acquiring the specifications of raw materials or components required to be used for producing the product according to the production parameters and acquiring the number of the raw materials or components required to be used for producing the product according to the number; a third obtaining module, configured to obtain a first geographical location where production equipment for producing the product is located, and obtain a second geographical location where a warehouse storing the raw materials or components is stored; a configuration module for configuring raw materials or components for producing the product from one or more warehouses nearest to the first geographic position according to the first geographic position, the second geographic position and the number of the raw materials or components, and generating configuration information, wherein the configuration information is used for indicating warehouses for preparing the raw materials or components, and preparing the specifications and the number of the raw materials or components from the warehouses; and the sending module is used for sending the configuration information to the corresponding warehouse.

Further, the method further comprises the following steps: the storage module is used for acquiring the cost and time consumed for transmitting the raw materials or the components after the warehouse receiving the configuration information successfully transmits the raw materials or the components to the first geographic position of the production equipment according to the configuration information; the cost and time are saved in a database.

Further, the configuration module is configured to: acquiring the cost and time corresponding to the order with the maximum similarity of the raw materials or components from the database under the condition that a plurality of warehouses closest to the first geographic position are provided; and selecting a warehouse with optimal cost and time as a warehouse for sending raw materials or components of the product to the production equipment.

Further, the configuration module is configured to: acquiring the corresponding cost and time of each warehouse, configuring the maximum cost of each warehouse as 1, and configuring the longest time in each warehouse as 1; taking the ratio of other costs to the maximum cost as a first value of the cost, and taking the ratio of other times to the maximum time as a second value of the time; taking a weighted sum of a first numerical value and a second numerical value of each warehouse as an evaluation value of the warehouse, wherein the weights of the first numerical value and the second numerical value are preconfigured; and selecting the warehouse with the minimum evaluation value as the warehouse with the optimal cost and time.

According to another aspect of the application, there is also included an electronic device including a memory and a processor; wherein the memory is configured to store one or more computer instructions, wherein the one or more computer instructions are executed by the processor to perform the method steps described above.

According to another aspect of the application, there is also included a readable storage medium having stored thereon computer instructions which when executed by a processor perform the above-described method steps.

In the embodiment of the application, the method comprises the steps of acquiring an order of a customer, and acquiring production parameters and quantity of products to be produced from the order of the customer; acquiring the specifications of raw materials or components required to be used for producing the product according to the production parameters, and acquiring the number of the raw materials or components required to be used for producing the product according to the number; acquiring a first geographical location of a production facility for producing the product and acquiring a second geographical location of a warehouse storing the raw materials or components; configuring raw materials or components for producing the product from one or more warehouses nearest to the first geographic position according to the first geographic position, the second geographic position and the number of the raw materials or components, and generating configuration information, wherein the configuration information is used for indicating warehouses for preparing the raw materials or the components and preparing the specifications and the number of the raw materials or the components from each warehouse; and sending the configuration information to a corresponding warehouse. The application solves the problems of low efficiency and influence on the production progress of the product caused by manually arranging raw materials or components in the production process of the customized product, thereby improving the rationality of the arrangement of the raw materials or the components and the production progress of the product.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description serve to explain the application. In the drawings:

fig. 1 is a flow chart of a network collaborative manufacturing construction method for service oriented manufacturing according to an embodiment of the present application.

Detailed Description

It should be noted that, without conflict, the embodiments of the present application and features of the embodiments may be combined with each other. The application will be described in detail below with reference to the drawings in connection with embodiments.

It should be noted that the steps illustrated in the flowcharts of the figures may be performed in a computer system such as a set of computer executable instructions, and that although a logical order is illustrated in the flowcharts, in some cases the steps illustrated or described may be performed in an order other than that illustrated herein.

Technical terms related to the following embodiments will be first described below.

VLAN (Virtual Local Area Network) is known as "virtual local area network".

Virtual Local Area Networks (VLANs) are a group of logical devices and users that are not limited by physical locations, and may be organized according to factors such as functions, departments, and applications, so that they communicate with each other as if they were in the same network segment, thereby obtaining a virtual local area network. The VLANs work in layers 2 and 3 of the OSI reference model, a VLAN is not necessarily a broadcast domain, communication between VLANs does not necessarily need to be routed through a gateway, and can be implemented by mutually allowing vlant ag, forming VLANs with different access control attributes, or by routers of layer 3, however, by allowing VLANID and vlant ag, a VLAN can be implemented as almost any information integration system architecture logical topology and access control in a local area network, and can be shared with other information systems sharing physical network links without interference. The VLAN can provide a virtual network topology architecture conforming to the service structure between the information service and the sub-service, and realize the access control function. Compared with the traditional LAN technology, the VLAN technology is more flexible, and has the following advantages: the management overhead of the movement, addition and modification of network devices is reduced; broadcast activity may be controlled; the security of the network can be improved.

In the following embodiments, a method for constructing a network collaborative manufacturing for service-oriented manufacturing is provided, fig. 1 is a flowchart of a method for constructing a network collaborative manufacturing for service-oriented manufacturing according to an embodiment of the present application, as shown in fig. 1, and steps involved in the method in fig. 1 are described below.

Step S102, obtaining the order of the customer, and obtaining the production parameters and the quantity of the products to be produced from the order of the customer.

And step S104, obtaining the specifications of raw materials or components required to be used for producing the product according to the production parameters, and obtaining the number of the raw materials or components required to be used for producing the product according to the number.

Step S106, obtaining a first geographical location where a production facility for producing the product is located, and obtaining a second geographical location of a warehouse storing the raw materials or components.

And step S108, configuring raw materials or components for producing the product from one or more warehouses closest to the first geographic position according to the first geographic position, the second geographic position and the number of the raw materials or components, and generating configuration information, wherein the configuration information is used for indicating warehouses for preparing the raw materials or components, and preparing the specifications and the number of the raw materials or components from the warehouses.

Step S110, sending the configuration information to a corresponding warehouse.

The problems of low efficiency and influence on the production progress caused by manually arranging raw materials or components in the production process of customized products are solved through the steps, so that the rationality of raw materials or component arrangement is improved, and the production progress of the products is also improved.

In one embodiment, after sending the configuration information to the corresponding repository, the method further comprises: after the warehouse which receives the configuration information successfully transmits the raw materials or the components to a first geographical position where the production equipment is located according to the configuration information, acquiring the cost and time consumed by transmitting the raw materials or the components; the cost and time are saved in a database.

In another embodiment, configuring raw materials or components for producing the product from one or more warehouses nearest to the first geographic location according to the first geographic location, the second geographic location, and the number of raw materials or components comprises: acquiring the cost and time corresponding to the order with the maximum similarity of the raw materials or components from the database under the condition that a plurality of warehouses closest to the first geographic position are provided; and selecting a warehouse with optimal cost and time as a warehouse for sending raw materials or components of the product to the production equipment.

In another embodiment, selecting a warehouse that is optimal in cost and time as a warehouse for raw materials or components that send the product to the production facility comprises: acquiring the corresponding cost and time of each warehouse, configuring the maximum cost of each warehouse as 1, and configuring the longest time in each warehouse as 1; taking the ratio of other costs to the maximum cost as a first value of the cost, and taking the ratio of other times to the maximum time as a second value of the time; taking a weighted sum of a first numerical value and a second numerical value of each warehouse as an evaluation value of the warehouse, wherein the weights of the first numerical value and the second numerical value are preconfigured; and selecting the warehouse with the minimum evaluation value as the warehouse with the optimal cost and time.

In the above alternative embodiments, the following aspects are involved:

network co-manufacturing solution design based on product design data, including in the solution: production material allocation, manufacturing unit deployment, production organization operation and the like.

The network communication system is constructed according to a scheme, wherein the scheme comprises the following steps: local network devices, private clouds, public cloud deployments, etc. The network communication system is built with consideration of the security of the network where the manufacturing equipment is located, so in this solution, all the manufacturing equipment is arranged in one local area network, and if the manufacturing equipment is distributed in different areas, the different areas where the manufacturing equipment is located are connected by using a virtual local area network. This ensures the safety of the manufacturing apparatus. In the local area network where the manufacturing equipment is located, the MAC address of each manufacturing equipment and the IP address of each manufacturing equipment are bound in advance, the IP address can be obtained only when the equipment with the MAC address in the white list is accessed into the local area network, the IP address can not be obtained after the equipment without the MAC address in the white list is accessed into the local area network, and the communication of the equipment in the local area network is limited.

A database for storing order data of customers, an analysis server for providing web pages that can be accessed by customers through a browser or a specific application, and a web server through which customers can place orders and customize production of products are arranged on a public cloud. The analysis server is used for processing the data extracted from the web page to obtain production data for producing the customized product, and the database is used for storing the data. The analysis server comprises at least two servers, one server is arranged on a public cloud and connected with a database and a webpage server (called a first analysis server), the other server is arranged on a private cloud and connected with manufacturing equipment (called a second analysis server) located in a local area network or a virtual local area network, and the manufacturing equipment only receives data and/or commands from the analysis server on the private cloud, namely the second analysis server. The first analysis server is connected with a second analysis server, the second analysis server is pre-configured with the IP address of the first analysis server, and the second analysis server receives data and/or commands from the first analysis server. This network layout may maximize the security of the manufacturing facility.

There are various ways of acquiring production data (or referred to as production parameters) through web pages, for example, acquiring an order from a customer, and extracting identification information of a product to be processed from the order; the identification information is used for uniquely identifying the product to be processed; acquiring identification information of the product to be processed from the order, and searching for component parts of the product to be processed according to the identification information; acquiring the characteristics of the product to be processed from the order, and adjusting and/or replacing the component parts according to the characteristics of the product to be processed to obtain the part characteristics of the product to be processed; searching a part model conforming to the part characteristics of the product to be processed from design software according to the part characteristics of the product to be processed, and assembling the part model into a product model; and generating production data for manufacturing a product corresponding to the product model according to the product model, and sending the production data to production equipment.

There are also various ways of storing data in a database (referred to as a first database), for example, obtaining an order submitted by a customer through a web page, storing various product parameters in the order in the database, wherein in the database product information is stored in a piece of original data, the piece of original data including a plurality of fields, each field being used to store a product parameter, the piece of data further including an order identifier for uniquely identifying the order, and a data identifier including a time stamp for indicating a time when the customer submitted the order, a customer identifier for uniquely identifying the customer, and an order status, the order status including: initial, modified and determined, wherein the initial is used for indicating that the piece of data is generated when the customer originally submits the order, the modified is used for indicating that the piece of data is generated when the customer modifies the order, and the determined is used for indicating that the piece of data is generated when the customer finally determines the order; determining that the client submits the modification to the order through a webpage, and acquiring the changed product parameters in the modified order; generating a piece of modification data in the database in response to modification of the order, wherein unchanged product parameters in a field for storing product parameters in the modification data are copied from the original data, and the acquired changed product parameters are stored in the modification data; the modification data further comprises the order identification and the data identification, the time stamp of the data identification of the modification data is used for indicating the time of the client modifying the order, and the order state of the data identification of the modification data is modification; each time a modification to the order is made, new modification data is generated.

Production material blending system

The production material allocation system is provided with a separate database (a second database) and a server, the second database stores the addresses of all production materials and the quantity of the materials, the server is connected with a second analysis server, and the second analysis server can only actively initiate data communication to the server, acquire required materials from the production material allocation system and allocate the materials by the production material allocation system.

And (3) using a production scheduling tool (MES and the like) to finish the production and manufacture of the unit level (part).

In the following, first, an application scheduling tool MES is used, and the MES is mainly used for production scheduling. MES production scheduling refers to the management of the flow or information of production units in the form of jobs, orders, batches, and orders. When an event occurs in a workshop, management personnel need to deal with in time. The production schedule can adjust the production plan of the workshop, handle reworking and waste, and control the product quantity of each production point through buffer area management. The following describes the flow of the MES business of the production management software.

1. Downloading orders for the production plan:

in the downloading process, the system can carry out corresponding standards and process development paths according to the work order processing technology products to generate various different process management information required to be processed in the current work order production and parameter data information of various processes: the work order information in the ERP system is scanned at fixed time, the work order which is not downloaded is searched, and when the social condition is met, the system can automatically download the work order into the MES system and set the status of the material work order as to-be-produced.

2. Production schedule input:

the MES system allows for manual entry of non-ERP orders, the input orders and ERP download orders being identical to management in subsequent processing.

3. Maintenance of production scheduling worksheets:

after the work order of the MES is generated from the order downloaded by the ERP, only one piece of work order processing technical information of the current enterprise order is generated, and some special situations of students are not fully considered.

Three aspects of production schedule work order adjustment are: first, single person information, second, working list processing technology paths, third, setting and adjusting parameters such as specific production process control, quality inspection method, production quality early warning and the like in each processing technology path.

(2) The maintenance of the work order information includes the work order number, the processed product, the planned production quantity, the planned start date, the planned finish date, and other attributes.

(3) The process information maintenance mainly comprises product processing processes (which can be added, inserted and deleted), and each process can be provided with control and quality control required by the production process. For outstanding workflows you can delete or change them.

4. Production management scheduling labor intensity degree:

the system arranges the work orders to each process and each production line main body to realize continuous and effective production, and provides two operation modules of automatic production scheduling and manual production scheduling, wherein the automatic production scheduling automatically finds out the scheduling result of a suboptimal solution based on factors such as a process path, equipment capacity, running condition, personnel configuration and the like of the work orders to be scheduled. According to the conditions of machine efficiency of product working procedures, batch size of work orders, time setting of conveying types and the like, the processing time of a certain working procedure of the work orders is automatically calculated, and therefore labor of scheduling personnel is simplified. The production arrangement efficiency is improved, the manual production arrangement can adjust the automatic production arrangement result, and the production arrangement result is displayed in a form and a Gantt chart mode.

Comprehensive inspection of production schedule: and pre-checking the consistency of the raw materials of each work order one by one according to the current stock of each raw material in a warehouse management system and the bill of materials of each work order according to the processing sequence of each work order determined by the work order. The color distinguishing expression in the production scheduling result diagram enables the plan to clearly know the whole production capacity and material condition, and related production activities are reasonably arranged.

And (3) issuing a production scheduling result: after the production scheduling is finished, the production scheduling information can be inquired in the system by each authorized post and role through the research result, and staff work at the posts can be arranged according to student information.

Through the implementation mode, the combined assembly and logistics distribution of the designed product are realized by utilizing the network collaborative manufacturing platform. The following functions are realized: 1. deconstructing and analyzing various design data; 2. designing a network collaborative manufacturing scheme; 3. planning and deploying manufacturing resources; 4. production efficiency and value energy consumption analysis; 5. and (5) building a production and manufacturing model and a database.

In this embodiment, there is provided an electronic device including a memory in which a computer program is stored, and a processor configured to run the computer program to perform the method in the above embodiment.

The above-described programs may be run on a processor or may also be stored in memory (or referred to as computer-readable media), including both permanent and non-permanent, removable and non-removable media, and information storage may be implemented by any method or technique. The information may be computer readable instructions, data structures, modules of a program, or other data. Examples of storage media for a computer include, but are not limited to, phase change memory (PRAM), static Random Access Memory (SRAM), dynamic Random Access Memory (DRAM), other types of Random Access Memory (RAM), read Only Memory (ROM), electrically Erasable Programmable Read Only Memory (EEPROM), flash memory or other memory technology, compact disc read only memory (CD-ROM), digital Versatile Discs (DVD) or other optical storage, magnetic cassettes, magnetic tape disk storage or other magnetic storage devices, or any other non-transmission medium, which can be used to store information that can be accessed by a computing device.

These computer programs may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart block or blocks and/or block diagram block or blocks, and corresponding steps may be implemented in different modules.

Such an apparatus or system is provided in this embodiment. The system is called a network collaborative manufacturing construction system for service oriented manufacturing, and comprises: the first acquisition module is used for acquiring orders of clients and acquiring production parameters and quantity of products to be produced from the orders of the clients; the second acquisition module is used for acquiring the specifications of raw materials or components required to be used for producing the product according to the production parameters and acquiring the number of the raw materials or components required to be used for producing the product according to the number; a third obtaining module, configured to obtain a first geographical location where production equipment for producing the product is located, and obtain a second geographical location where a warehouse storing the raw materials or components is stored; a configuration module for configuring raw materials or components for producing the product from one or more warehouses nearest to the first geographic position according to the first geographic position, the second geographic position and the number of the raw materials or components, and generating configuration information, wherein the configuration information is used for indicating warehouses for preparing the raw materials or components, and preparing the specifications and the number of the raw materials or components from the warehouses; and the sending module is used for sending the configuration information to the corresponding warehouse.

The system or the device is used for realizing the functions of the method in the above embodiment, and each module in the system or the device corresponds to each step in the method, which has been described in the method, and will not be described herein.

Optionally, the method further comprises: the storage module is used for acquiring the cost and time consumed for transmitting the raw materials or the components after the warehouse receiving the configuration information successfully transmits the raw materials or the components to the first geographic position of the production equipment according to the configuration information; the cost and time are saved in a database.

Optionally, the configuration module is configured to: acquiring the cost and time corresponding to the order with the maximum similarity of the raw materials or components from the database under the condition that a plurality of warehouses closest to the first geographic position are provided; and selecting a warehouse with optimal cost and time as a warehouse for sending raw materials or components of the product to the production equipment.

Optionally, the configuration module is configured to: acquiring the corresponding cost and time of each warehouse, configuring the maximum cost of each warehouse as 1, and configuring the longest time in each warehouse as 1; taking the ratio of other costs to the maximum cost as a first value of the cost, and taking the ratio of other times to the maximum time as a second value of the time; taking a weighted sum of a first numerical value and a second numerical value of each warehouse as an evaluation value of the warehouse, wherein the weights of the first numerical value and the second numerical value are preconfigured; and selecting the warehouse with the minimum evaluation value as the warehouse with the optimal cost and time.

The problems of low efficiency and influence on the production progress caused by manually arranging raw materials or components in the production process of customized products are solved through the steps, so that the rationality of raw materials or component arrangement is improved, and the production progress of the products is also improved.

The foregoing is merely exemplary of the present application and is not intended to limit the present application. Various modifications and variations of the present application will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the application are to be included in the scope of the claims of the present application.

Claims (10)

1. The network collaborative manufacturing construction method for service-oriented manufacturing is characterized by comprising the following steps:

acquiring an order of a customer, and acquiring production parameters and quantity of products to be produced from the order of the customer;

acquiring the specifications of raw materials or components required to be used for producing the product according to the production parameters, and acquiring the number of the raw materials or components required to be used for producing the product according to the number;

acquiring a first geographical location of a production facility for producing the product and acquiring a second geographical location of a warehouse storing the raw materials or components;

configuring raw materials or components for producing the product from one or more warehouses nearest to the first geographic position according to the first geographic position, the second geographic position and the number of the raw materials or components, and generating configuration information, wherein the configuration information is used for indicating warehouses for preparing the raw materials or the components and preparing the specifications and the number of the raw materials or the components from each warehouse;

and sending the configuration information to a corresponding warehouse.

2. The method of claim 1, wherein after transmitting the configuration information to the corresponding repository, the method further comprises:

after the warehouse which receives the configuration information successfully transmits the raw materials or the components to a first geographical position where the production equipment is located according to the configuration information, acquiring the cost and time consumed by transmitting the raw materials or the components;

the cost and time are saved in a database.

3. The method of claim 2, wherein configuring raw materials or components for producing the product from one or more warehouses nearest the first geographic location based on the first geographic location, the second geographic location, and the number of raw materials or components comprises:

acquiring the cost and time corresponding to the order with the maximum similarity of the raw materials or components from the database under the condition that a plurality of warehouses closest to the first geographic position are provided;

and selecting a warehouse with optimal cost and time as a warehouse for sending raw materials or components of the product to the production equipment.

4. A method according to claim 3, wherein selecting a warehouse that is cost and time optimal as a warehouse for raw materials or components that send the product to the production facility comprises:

acquiring the corresponding cost and time of each warehouse, configuring the maximum cost of each warehouse as 1, and configuring the longest time in each warehouse as 1;

taking the ratio of other costs to the maximum cost as a first value of the cost, and taking the ratio of other times to the maximum time as a second value of the time;

taking a weighted sum of a first numerical value and a second numerical value of each warehouse as an evaluation value of the warehouse, wherein the weights of the first numerical value and the second numerical value are preconfigured;

and selecting the warehouse with the minimum evaluation value as the warehouse with the optimal cost and time.

5. A network collaborative manufacturing building system for service oriented manufacturing, comprising:

the first acquisition module is used for acquiring orders of clients and acquiring production parameters and quantity of products to be produced from the orders of the clients;

the second acquisition module is used for acquiring the specifications of raw materials or components required to be used for producing the product according to the production parameters and acquiring the number of the raw materials or components required to be used for producing the product according to the number;

a third obtaining module, configured to obtain a first geographical location where production equipment for producing the product is located, and obtain a second geographical location where a warehouse storing the raw materials or components is stored;

a configuration module for configuring raw materials or components for producing the product from one or more warehouses nearest to the first geographic position according to the first geographic position, the second geographic position and the number of the raw materials or components, and generating configuration information, wherein the configuration information is used for indicating warehouses for preparing the raw materials or components, and preparing the specifications and the number of the raw materials or components from the warehouses;

and the sending module is used for sending the configuration information to the corresponding warehouse.

6. The system of claim 5, further comprising:

the storage module is used for acquiring the cost and time consumed for transmitting the raw materials or the components after the warehouse receiving the configuration information successfully transmits the raw materials or the components to the first geographic position of the production equipment according to the configuration information; the cost and time are saved in a database.

7. The system of claim 6, wherein the configuration module is configured to:

acquiring the cost and time corresponding to the order with the maximum similarity of the raw materials or components from the database under the condition that a plurality of warehouses closest to the first geographic position are provided;

and selecting a warehouse with optimal cost and time as a warehouse for sending raw materials or components of the product to the production equipment.

8. The system of claim 7, wherein the configuration module is configured to:

acquiring the corresponding cost and time of each warehouse, configuring the maximum cost of each warehouse as 1, and configuring the longest time in each warehouse as 1;

taking the ratio of other costs to the maximum cost as a first value of the cost, and taking the ratio of other times to the maximum time as a second value of the time;

taking a weighted sum of a first numerical value and a second numerical value of each warehouse as an evaluation value of the warehouse, wherein the weights of the first numerical value and the second numerical value are preconfigured;

and selecting the warehouse with the minimum evaluation value as the warehouse with the optimal cost and time.

9. An electronic device includes a memory and a processor; wherein the memory is for storing one or more computer instructions, wherein the one or more computer instructions are executed by the processor to implement the method steps of any of claims 1 to 4.

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