CN115641061A - Material management method and device - Google Patents

Abstract

The invention relates to the technical field of warehouse management, and particularly discloses a material management method, which comprises the steps of receiving an order generation request sent by an ordering party, and generating order information; recursively inquiring a production flow corresponding to the order information in a recorded production flow library, determining a demand material based on the production flow, counting the demand material and inserting an order number to obtain a demand material table with the order number as an index; and receiving a material management request containing material parameters sent by a supplier, and determining a storage area with the order number as a label according to the required material list. The method comprises the steps of generating a demand table with order numbers as indexes according to order information, when receiving materials to be stored, segmenting the materials to be stored according to the demand table, and storing the materials to be stored in different storage areas; when a certain order is to be produced, the required raw materials can be easily obtained, a weighing link is not needed, and the production efficiency is greatly improved.

Description

Material management method and device

Technical Field

The invention relates to the technical field of warehousing management, in particular to a material management method and device.

Background

The material management is a general term of a series of management activities such as planning, organization, control and the like, such as purchasing, acceptance, supply, storage, distribution, reasonable use, saving, comprehensive utilization and the like of various materials required by the production and operation activities of enterprises. For production type enterprises, when a new project needs to be started, the required quantity of materials needs to be drawn up according to project requirements, then the materials are registered in a warehouse to be taken, and when the materials are taken out of the warehouse, the types and the quantity of the materials need to be checked and recorded, the total quantity of the materials in the warehouse is updated, and the materials are convenient to manage.

In the process, if the storage process of the materials is not convenient enough, the working efficiency is affected; most of the existing storage frameworks store materials of the same type together, and when some materials are needed, the materials are weighed in corresponding areas; it can be thought that many products require more than one raw material, and when the quantity of the raw materials is large, the proportion occupied by the weighing link is very large, and the efficiency is extremely influenced.

Disclosure of Invention

The present invention is directed to a method and an apparatus for managing materials, so as to solve the problems in the background art.

In order to achieve the purpose, the invention provides the following technical scheme:

a method of material management, the method comprising:

receiving an order generation request sent by an orderer, acquiring area information of the orderer, determining a quantity limit according to the area information, receiving the order quantity input by the orderer based on the quantity limit, and generating order information; the order information contains an order number;

recursively inquiring a production flow corresponding to the order information in a recorded production flow library, determining a demand material based on the production flow, counting the demand material and inserting an order number to obtain a demand material table with the order number as an index;

receiving a material management request containing material parameters sent by a supplier, and determining a storage area with an order number as a label according to the required material list;

acquiring warehouse parameters in real time, and generating a working instruction for a preset environment controller according to the warehouse parameters; the environmental controller includes a temperature regulator and a humidity regulator.

As a further scheme of the invention: the method comprises the steps of receiving an order generation request sent by an orderer, acquiring area information of the orderer, determining quantity limit according to the area information, receiving order quantity input by the orderer based on the quantity limit, and generating the order information, wherein the steps comprise:

receiving an order generation request sent by an orderer, and acquiring area information and scale parameters of the orderer; the scale parameters comprise sales and investment cost;

inputting the scale parameters into a trained enterprise evaluation model to obtain influence scores;

inquiring other orderers in the region information, counting the influence scores of all orderers, and determining the supply proportion of the orderer sending an order generation request according to the influence scores;

acquiring the capacity of a supplier for the regional information, and determining the quantity limit of an orderer sending an order generation request according to the supply proportion and the capacity;

and receiving the order quantity input by the orderer based on the quantity limit to generate order information.

As a further scheme of the invention: the step of receiving the order quantity input by the orderer based on the quantity quota and generating order information comprises the following steps:

receiving the order quantity input by an orderer based on the quantity quota, and calculating the finished product time according to the order quantity;

obtaining predicted logistics data between the goods ordering party and the finished product time; the predicted logistics data comprises logistics time;

calculating delivery date according to the finished product time and the logistics time, and sending the order quantity and the delivery date to an ordering party;

when confirmation information fed back by an orderer is received, order information including a determination date and a delivery date is generated.

As a further scheme of the invention: the step of recursively inquiring the production flow corresponding to the order information in the recorded production flow library, determining the demand materials based on the production flow, counting the demand materials and inserting the order numbers to obtain the demand material table with the order numbers as indexes comprises the following steps:

inquiring the production flow in the recorded production flow library, and determining production raw materials according to the production flow;

judging whether the production raw materials are to-be-processed raw materials or not, inquiring the production flow of the production raw materials when the production raw materials are to-be-processed raw materials, and performing recursive circulation until all the production raw materials are purchase raw materials;

determining the physical characteristics of each purchased raw material according to the number of the orders, counting all the purchased raw materials and the physical characteristics thereof, reading and connecting the order numbers to obtain a required material list taking the order numbers as indexes; the physical characteristics are used to characterize how much of the material was purchased.

As a further scheme of the invention: the step of receiving a material management request containing material parameters sent by a supplier and determining a storage area with an order number as a label according to the required material list comprises the following steps:

receiving a material management request sent by a supplier, and acquiring the name and physical characteristics of the material, wherein the unit of the physical characteristics comprises quantity, quality and volume;

sequentially reading the required material tables corresponding to the order numbers, inquiring delivery dates according to the order numbers, and sequencing the required material tables according to the delivery dates;

and segmenting the material to be stored according to the requirement material table, and determining the storage area with the order number as the label.

As a further scheme of the invention: the step of segmenting the material to be stored according to the required material list and determining the storage area with the order number as the label comprises the following steps:

matching the purchased raw materials in the required material list according to the material names, and inquiring corresponding physical characteristics;

cutting the material to be stored according to the physical characteristics, and inserting the material into a storage area with the order number as a label;

the storage area with the order number as the label is established when the order number is generated.

As a further scheme of the invention: the step of acquiring warehouse parameters in real time and generating a working instruction for a preset environment controller according to the warehouse parameters comprises the following steps:

acquiring warehouse parameters in real time according to preset sensing equipment; the warehouse parameters include temperature and humidity;

acquiring weather prediction data in real time, and correcting warehouse parameters according to the weather prediction data;

determining a working instruction according to the corrected warehouse parameters, and sending the working instruction to a preset environment controller;

wherein the environmental controller includes a temperature regulator and a humidity regulator.

The technical scheme of the invention also provides a material management device, which comprises:

the order information generation module is used for receiving an order generation request sent by an orderer, acquiring the area information of the orderer, determining the quantity limit according to the area information, receiving the order quantity input by the orderer based on the quantity limit and generating the order information; the order information contains an order number;

the demand table determining module is used for recursively inquiring the production flow corresponding to the order information in the recorded production flow library, determining demand materials based on the production flow, counting the demand materials and inserting order numbers to obtain a demand material table taking the order numbers as indexes;

the storage area determining module is used for receiving a material management request containing material parameters sent by a supplier and determining a storage area with an order number as a label according to the required material list;

the environment adjusting module is used for acquiring warehouse parameters in real time and generating a working instruction for a preset environment controller according to the warehouse parameters; the environmental controller includes a temperature regulator and a humidity regulator.

As a further scheme of the invention: the order information generating module comprises:

the parameter acquisition unit is used for receiving an order generation request sent by an orderer and acquiring the area information and the scale parameter of the orderer; the scale parameters comprise sales and investment cost;

the influence score calculation unit is used for inputting the scale parameters into a trained enterprise evaluation model to obtain influence scores;

the proportion generating unit is used for inquiring other orderers in the area information, counting the influence scores of all the orderers and determining the supply proportion of the orderer sending the order generation request according to the influence scores;

the quota determining unit is used for acquiring the capacity of a supplier for the regional information and determining the quantity quota of the orderer sending the order generation request according to the supply proportion and the capacity;

and the quantity acquisition unit is used for receiving the order quantity input by the orderer based on the quantity limit and generating order information.

As a further scheme of the invention: the requirement table determining module comprises:

the raw material determining unit is used for inquiring the production flow in the recorded production flow library and determining the production raw materials according to the production flow;

the recursion cycle unit is used for judging whether the production raw materials are to-be-processed raw materials or not, inquiring the production flow of the production raw materials when the production raw materials are to-be-processed raw materials, and carrying out recursion cycle until all the production raw materials are purchase raw materials;

the statistical generation unit is used for determining the physical characteristics of each purchased raw material according to the number of the orders, counting all the purchased raw materials and the physical characteristics thereof, reading and connecting the order numbers to obtain a required material list with the order numbers as indexes; the physical characteristics are used to characterize how much of the material was purchased.

Compared with the prior art, the invention has the beneficial effects that: the method comprises the steps of generating a demand table with order numbers as indexes according to order information, when receiving materials to be stored, segmenting the materials to be stored according to the demand table, and storing the materials to be stored in different storage areas; when a certain order is to be produced, the required raw materials can be easily obtained, a weighing link is not needed, and the production efficiency is greatly improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention.

FIG. 1 is a flow diagram of a method of material management.

Fig. 2 is a first sub-flow block diagram of a material management method.

Fig. 3 is a second sub-flow block diagram of a method of material management.

Fig. 4 is a third sub-flow block diagram of a material management method.

Fig. 5 is a fourth sub-flow block diagram of a material management method.

Fig. 6 is a block diagram showing a composition structure of the material management apparatus.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and do not limit the invention.

Example 1

Fig. 1 is a flow chart of a material management method, and in an embodiment of the present invention, a material management method includes steps S100 to S400:

step S100: receiving an order generation request sent by an orderer, acquiring area information of the orderer, determining a quantity limit according to the area information, receiving the order quantity input by the orderer based on the quantity limit, and generating order information; the order information contains an order number;

the order generation request is sent by an order supplier, and the existing order information generation architecture is that the order supplier inputs a quantity and generates an order according to the quantity, but sometimes, the capacity of the order supplier is insufficient, so the quantity input by the order supplier needs to be distributed; the assigned reference is the regional information of the orderer.

Step S200: recursively inquiring a production flow corresponding to the order information in a recorded production flow library, determining a demand material based on the production flow, counting the demand material and inserting an order number to obtain a demand material table with the order number as an index;

after the order information is generated, the production flow of the order information can be inquired by means of a preset production flow library, and the required materials are determined according to the production flow to obtain a required material table; it should be noted that the required material is a material to be purchased, and if a raw material required to be processed by the enterprise exists in the production flow, the production flow of the raw material needs to be queried, further decomposition is performed, and finally a raw material which cannot be continuously decomposed is determined to obtain a required material table;

step S300: receiving a material management request containing material parameters sent by a supplier, and determining a storage area with an order number as a label according to the required material list;

the material management request is sent by a supplier in a mode that when a worker stores materials, the material management request is sent through an information sending port at a warehouse, wherein the information sending port can be a common button or an App installed in a smart phone; and after the storage area is determined, the information is fed back to the staff to guide the storage process.

Step S400: acquiring warehouse parameters in real time, and generating a working instruction for a preset environment controller according to the warehouse parameters; the environment controller comprises a temperature regulator and a humidity regulator;

when the material is stored in the warehouse, the warehouse needs to be monitored in real time, the environmental state is adjusted through the environmental controller, and the material is prevented from being damaged.

Fig. 2 is a first sub-flow block diagram of the material management method, where the step of receiving an order generation request sent by an orderer, acquiring area information of the orderer, determining a quantity limit according to the area information, receiving an order quantity input by the orderer based on the quantity limit, and generating the order information includes steps S101 to S105:

step S101: receiving an order generation request sent by an orderer, and acquiring area information and scale parameters of the orderer; the scale parameters comprise sales and investment cost;

step S102: inputting the scale parameters into a trained enterprise evaluation model to obtain influence scores;

step S103: inquiring other orderers in the region information, counting the influence scores of all orderers, and determining the supply proportion of the orderer sending an order generation request according to the influence scores;

step S104: acquiring the capacity of a supplier for the regional information, and determining the quantity limit of an orderer sending an order generation request according to the supply proportion and the capacity;

step S105: and receiving the order quantity input by the orderer based on the quantity quota, and generating order information.

The steps S101 to S105 describe the generation process of the order information specifically, and the key point is to determine the influence of the orderer in the area where the orderer is located, determine the order proportion of each orderer according to the influence, and further determine how many orders the orderer can order at most according to the capacity, that is, the data limit;

further, the step of receiving the order quantity input by the orderer based on the quantity quota and generating order information comprises:

receiving the order quantity input by an orderer based on the quantity quota, and calculating the finished product time according to the order quantity;

obtaining predicted logistics data between the goods ordering party and the finished product time; the predicted logistics data comprises logistics time;

calculating delivery date according to the finished product time and the logistics time, and sending the order quantity and the delivery date to an ordering party;

when confirmation information fed back by an orderer is received, order information including a determination date and a delivery date is generated.

The order information can be related to time information, and firstly, a finished product time is determined according to the order quantity, which can be determined by a worker according to the production flow; then, based on the product time and the estimated logistics time, a delivery date can be determined; finally, the delivery date is sent to the orderer, and if the orderer agrees, an order message is determined.

Fig. 3 is a second sub-flow block diagram of the material management method, where the step of recursively querying the production flow corresponding to the order information in the recorded production flow library, determining the demand material based on the production flow, counting the demand material and inserting the order number into the demand material table to obtain the demand material table indexed by the order number includes steps S201 to S203:

step S201: inquiring the production flow in the recorded production flow library, and determining production raw materials according to the production flow;

step S202: judging whether the production raw materials are to-be-processed raw materials or not, inquiring the production flow of the production raw materials when the production raw materials are to-be-processed raw materials, and performing recursive circulation until all the production raw materials are purchase raw materials;

step S203: determining the physical characteristics of each purchased raw material according to the number of the orders, counting all the purchased raw materials and the physical characteristics thereof, reading and connecting the order numbers to obtain a required material list taking the order numbers as indexes; the physical characteristics are used to characterize how much of the material was purchased.

The generation process of the demand material table is specifically described, and the purchase material is the demand material; it should be noted that the physical characteristics are different from the unit of purchased materials, and some are in the unit of quantity and some are in the unit of weight, and they are collectively called physical characteristics.

Fig. 4 is a third sub-flow block diagram of the material management method, where the step of receiving a material management request containing material parameters sent by a supplier and determining a storage area with an order number as a tag according to the required material table includes steps S301 to S303:

step S301: receiving a material management request sent by a supplier, and acquiring material names and physical characteristics thereof, wherein the unit of the physical characteristics comprises quantity, quality and volume;

step S302: sequentially reading the required material tables corresponding to the order numbers, inquiring delivery dates according to the order numbers, and sequencing the required material tables according to the delivery dates;

step S303: and segmenting the material to be stored according to the required material table, and determining a storage area with the order number as a label.

The steps from S301 to S303 are specifically described, the cutting process of the materials to be stored is not difficult, that is, when a worker needs to store a stack of materials, according to the requirement corresponding to each order, part of the materials are sequentially extracted from the stack of materials and stored in the storage area corresponding to the order; different from the traditional storage mode, the raw materials are classified according to orders instead of types, so that the production efficiency can be greatly improved.

Further, the step of segmenting the material to be stored according to the required material list and determining the storage area with the order number as the label comprises the following steps:

matching the purchased raw materials in the required material list according to the material name, and inquiring corresponding physical characteristics;

cutting the material to be stored according to the physical characteristics, and inserting the material into a storage area with the order number as a label;

the storage area with the order number as the label is established when the order number is generated.

The splitting process is a matching process, and the matched parameters are physical characteristics, for example, the material to be stored is one ton of wheat, and then one hundred kilograms of wheat are needed in a required material table corresponding to a certain order, so one hundred kilograms of wheat are needed to be extracted from the ton of wheat for storage.

Fig. 5 is a fourth sub-flow block diagram of the material management method, where the step of acquiring the warehouse parameters in real time and generating the working instruction for the preset environment controller according to the warehouse parameters includes steps S401 to S403:

step S401: acquiring warehouse parameters in real time according to preset sensing equipment; the warehouse parameters include temperature and humidity;

step S402: acquiring weather prediction data in real time, and correcting warehouse parameters according to the weather prediction data;

step S403: determining a working instruction according to the corrected warehouse parameters, and sending the working instruction to a preset environment controller;

wherein the environmental controller includes a temperature regulator and a humidity regulator.

The environment adjusting process is specifically described, and it is worth mentioning that after the sensing device acquires the warehouse parameters, weather prediction data needs to be acquired in real time, the data can be completed through common weather services, and the warehouse parameters can be corrected according to the weather prediction data, so that the environment adjusting process has some predictability and is more appropriately realized; if the environmental parameters are acquired and then adjusted, a certain delay is generated in the specific adjusting process.

Example 2

Fig. 6 is a block diagram of a composition structure of a material management device, in an embodiment of the present invention, a material management device, where the device 10 includes:

the order information generating module 11 is configured to receive an order generating request sent by an orderer, acquire region information of the orderer, determine a quantity limit according to the region information, receive an order quantity input by the orderer based on the quantity limit, and generate order information; the order information contains an order number;

a demand table determining module 12, configured to recursively query a production process corresponding to the order information in a recorded production process library, determine a demand material based on the production process, count the demand material, and insert an order number into the demand material, so as to obtain a demand material table indexed by the order number;

the storage area determining module 13 is configured to receive a material management request containing material parameters sent by a supplier, and determine a storage area with an order number as a tag according to the required material table;

the environment adjusting module 14 is configured to obtain warehouse parameters in real time, and generate a working instruction for a preset environment controller according to the warehouse parameters; the environmental controller includes a temperature regulator and a humidity regulator.

Further, the order information generating module 11 includes:

the parameter acquisition unit is used for receiving an order generation request sent by an orderer and acquiring the area information and the scale parameter of the orderer; the scale parameters comprise sales and investment cost;

the influence score calculation unit is used for inputting the scale parameters into a trained enterprise evaluation model to obtain influence scores;

the proportion generating unit is used for inquiring other orderers in the area information, counting the influence scores of all the orderers and determining the supply proportion of the orderer sending the order generation request according to the influence scores;

the quota determining unit is used for acquiring the capacity of a supplier for the regional information and determining the quantity quota of the orderer sending the order generation request according to the supply proportion and the capacity;

and the quantity acquisition unit is used for receiving the quantity of the order input by the orderer based on the quantity limit and generating order information.

Specifically, the requirement table determining module 12 includes:

the raw material determining unit is used for inquiring the production process in the recorded production process library and determining the production raw materials according to the production process;

the recursion cycle unit is used for judging whether the production raw materials are to-be-processed raw materials or not, inquiring the production flow of the production raw materials when the production raw materials are to-be-processed raw materials, and carrying out recursion cycle until all the production raw materials are purchase raw materials;

the statistics generation unit is used for determining the physical characteristics of each purchased raw material according to the number of the orders, counting all the purchased raw materials and the physical characteristics thereof, reading and connecting the order numbers to obtain a required material list taking the order numbers as indexes; the physical characteristics are used to characterize how much of the material was purchased.

The functions that can be performed by the material management method are performed by a computer device that includes one or more processors and one or more memories having at least one program code stored therein, the program code being loaded and executed by the one or more processors to perform the functions of the material management method.

The processor fetches instructions and analyzes the instructions one by one from the memory, then completes corresponding operations according to the instruction requirements, generates a series of control commands, enables all parts of the computer to automatically, continuously and coordinately act to form an organic whole, realizes the input of programs, the input of data, the operation and the output of results, and the arithmetic operation or the logic operation generated in the process is completed by the arithmetic unit; the Memory comprises a Read-Only Memory (ROM) for storing a computer program, and a protection device is arranged outside the Memory.

Illustratively, the computer program may be partitioned into one or more modules, stored in memory and executed by a processor, to implement the invention. One or more of the modules may be a series of computer program instruction segments capable of performing certain functions, which are used to describe the execution of the computer program in the terminal device.

Those skilled in the art will appreciate that the above description of the service device is merely exemplary and not limiting of the terminal device, and may include more or less components than those described, or combine certain components, or different components, such as may include input output devices, network access devices, buses, etc.

The Processor may be a Central Processing Unit (CPU), other general purpose Processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), an off-the-shelf Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic, discrete hardware components, etc. The general-purpose processor may be a microprocessor or the processor may be any conventional processor or the like, which is the control center of the terminal equipment and connects the various parts of the entire user terminal using various interfaces and lines.

The memory may be used to store computer programs and/or modules, and the processor may implement various functions of the terminal device by operating or executing the computer programs and/or modules stored in the memory and calling data stored in the memory. The memory mainly comprises a storage program area and a storage data area, wherein the storage program area can store an operating system, application programs (such as an information acquisition template display function, a product information publishing function and the like) required by at least one function and the like; the storage data area may store data created according to the use of the berth-state display system (e.g., product information acquisition templates corresponding to different product types, product information that needs to be issued by different product providers, etc.), and the like. In addition, the memory may include high speed random access memory, and may also include non-volatile memory, such as a hard disk, a memory, a plug-in hard disk, a Smart Media Card (SMC), a Secure Digital (SD) Card, a Flash memory Card (Flash Card), at least one magnetic disk storage device, a Flash memory device, or other volatile solid state storage device.

The terminal device integrated modules/units, if implemented in the form of software functional units and sold or used as separate products, may be stored in a computer readable storage medium. Based on such understanding, all or part of the modules/units in the system according to the above embodiment may be implemented by a computer program, which may be stored in a computer-readable storage medium and used by a processor to implement the functions of the embodiments of the system. Wherein the computer program comprises computer program code, which may be in the form of source code, object code, an executable file or some intermediate form, etc. The computer readable medium may include: any entity or device capable of carrying computer program code, recording medium, U.S. disk, removable hard disk, magnetic disk, optical disk, computer Memory, read-Only Memory (ROM), random Access Memory (RAM), electrical carrier wave signals, telecommunications signals, software distribution media, and the like.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising a … …" does not exclude the presence of another identical element in a process, method, article, or apparatus that comprises the element.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. A method of material management, the method comprising:

receiving an order generation request sent by an orderer, acquiring area information of the orderer, determining a quantity limit according to the area information, receiving the order quantity input by the orderer based on the quantity limit, and generating order information; the order information contains an order number;

recursively inquiring a production flow corresponding to the order information in a recorded production flow library, determining a demand material based on the production flow, counting the demand material and inserting an order number to obtain a demand material table with the order number as an index;

receiving a material management request containing material parameters sent by a supplier, and determining a storage area with an order number as a label according to the required material list;

acquiring warehouse parameters in real time, and generating a working instruction for a preset environment controller according to the warehouse parameters; the environmental controller includes a temperature regulator and a humidity regulator.

2. The material management method according to claim 1, wherein the step of receiving an order generation request from an orderer, obtaining area information of the orderer, determining a quantity limit according to the area information, receiving an order quantity input by the orderer based on the quantity limit, and generating the order information comprises:

receiving an order generation request sent by an orderer, and acquiring area information and scale parameters of the orderer; the scale parameters comprise sales and investment cost;

inputting the scale parameters into a trained enterprise evaluation model to obtain influence scores;

inquiring other orderers in the region information, counting the influence scores of all orderers, and determining the supply proportion of the orderer sending an order generation request according to the influence scores;

acquiring the capacity of a supplier for the regional information, and determining the quantity limit of an orderer sending an order generation request according to the supply proportion and the capacity;

and receiving the order quantity input by the orderer based on the quantity quota, and generating order information.

3. The material management method of claim 2, wherein the step of generating order information based on the quantity limit receiving an order quantity entered by an order sender comprises:

receiving the order quantity input by an orderer based on the quantity quota, and calculating the finished product time according to the order quantity;

obtaining predicted logistics data between the goods ordering party and the finished product time; the predicted logistics data comprises logistics time;

calculating delivery date according to the finished product time and the logistics time, and sending the order quantity and the delivery date to an ordering party;

when confirmation information fed back by an orderer is received, order information including a determination date and a delivery date is generated.

4. The material management method according to claim 1, wherein the step of recursively querying the production process corresponding to the order information in the filed production process library, determining a demand material based on the production process, counting the demand material and inserting an order number into the demand material library to obtain a demand material table indexed by the order number comprises:

inquiring the production flow in the recorded production flow library, and determining production raw materials according to the production flow;

judging whether the production raw materials are to-be-processed raw materials or not, inquiring the production flow of the production raw materials when the production raw materials are to-be-processed raw materials, and recursively circulating until all the production raw materials are purchase raw materials;

determining the physical characteristics of each purchased raw material according to the number of the orders, counting all the purchased raw materials and the physical characteristics thereof, reading and connecting the order numbers to obtain a required material list taking the order numbers as indexes; the physical characteristics are used to characterize how much of the material was purchased.

5. The material management method according to claim 1, wherein the step of receiving a material management request containing material parameters from a supplier and determining a storage area labeled with an order number according to the required material table comprises:

receiving a material management request sent by a supplier, and acquiring material names and physical characteristics thereof, wherein the unit of the physical characteristics comprises quantity, quality and volume;

sequentially reading the required material tables corresponding to the order numbers, inquiring delivery dates according to the order numbers, and sequencing the required material tables according to the delivery dates;

and segmenting the material to be stored according to the requirement material table, and determining the storage area with the order number as the label.

6. The material management method according to claim 5, wherein the step of dividing the material to be stored according to the required material list and determining the storage area with the order number as the label comprises:

matching the purchased raw materials in the required material list according to the material names, and inquiring corresponding physical characteristics;

cutting the material to be stored according to the physical characteristics, and inserting the material into a storage area with the order number as a label;

the storage area with the order number as the label is established when the order number is generated.

7. The material management method according to claim 6, wherein the step of obtaining warehouse parameters in real time and generating working instructions for a preset environment controller according to the warehouse parameters comprises:

acquiring warehouse parameters in real time according to preset sensing equipment; the warehouse parameters include temperature and humidity;

acquiring weather prediction data in real time, and correcting warehouse parameters according to the weather prediction data;

determining a working instruction according to the corrected warehouse parameters, and sending the working instruction to a preset environment controller;

wherein the environmental controller includes a temperature regulator and a humidity regulator.

8. An apparatus for managing materials, the apparatus comprising:

the order information generation module is used for receiving an order generation request sent by an orderer, acquiring the area information of the orderer, determining the quantity limit according to the area information, receiving the order quantity input by the orderer based on the quantity limit and generating the order information; the order information contains an order number;

the demand table determining module is used for recursively inquiring the production flow corresponding to the order information in the recorded production flow library, determining demand materials based on the production flow, counting the demand materials and inserting order numbers to obtain a demand material table taking the order numbers as indexes;

the storage area determining module is used for receiving a material management request containing material parameters sent by a supplier and determining a storage area with an order number as a label according to the required material list;

the environment adjusting module is used for acquiring warehouse parameters in real time and generating a working instruction for a preset environment controller according to the warehouse parameters; the environmental controller includes a temperature regulator and a humidity regulator.

9. The material management apparatus of claim 8, wherein the order information generation module comprises:

the parameter acquisition unit is used for receiving an order generation request sent by an orderer and acquiring the area information and the scale parameter of the orderer; the scale parameters comprise sales and investment cost;

the influence score calculation unit is used for inputting the scale parameters into a trained enterprise evaluation model to obtain influence scores;

the proportion generating unit is used for inquiring other orderers in the area information, counting the influence scores of all the orderers and determining the supply proportion of the orderer sending the order generation request according to the influence scores;

the quota determining unit is used for acquiring the capacity of a supplier for the regional information and determining the quantity quota of the orderer sending the order generation request according to the supply proportion and the capacity;

and the quantity acquisition unit is used for receiving the order quantity input by the orderer based on the quantity limit and generating order information.

10. The material management apparatus of claim 8, wherein the requirement table determining module comprises:

the raw material determining unit is used for inquiring the production flow in the recorded production flow library and determining the production raw materials according to the production flow;

the recursion cycle unit is used for judging whether the production raw materials are to-be-processed raw materials or not, inquiring the production flow of the production raw materials when the production raw materials are to-be-processed raw materials, and carrying out recursion cycle until all the production raw materials are purchase raw materials;

the statistical generation unit is used for determining the physical characteristics of each purchased raw material according to the number of the orders, counting all the purchased raw materials and the physical characteristics thereof, reading and connecting the order numbers to obtain a required material list with the order numbers as indexes; the physical characteristics are used to characterize how much of the material was purchased.

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