CN109992806A - Industrialized data processing method, electronic equipment and storage medium for building decoration base - Google Patents

Abstract

The invention discloses an industrialized data processing method, an electronic device and a storage medium for a building decoration base layer. The method includes: in response to a user's fetching instruction, fetching the decoration base layer module data corresponding to the fetching instruction as the current decoration base layer module data; Receive the personalized configuration data about the current decorative base module data input by the user, modify the material information of the current decorative base module data according to the personalized configuration data to obtain the combined decorative base module data; retrieve the customization specification corresponding to the current decorative base module data As the current customization specification, the data of the combined decoration module is verified, and if the data of the combined decoration base module meets the current customization specification, the module data list and the bill of materials are output. The invention takes the modularization of architectural decoration parts as the core, the industrialized organization of production as the basis, and the on-site assembly construction as the means to realize a new assembly-type basic system that adapts to the industrialization of the Internet era.

Description

Industrialized data processing method, electronic equipment and storage medium for building decoration base

technical field

The invention relates to the technical field of architectural decoration, in particular to an industrialized data processing method, an electronic device and a storage medium of an architectural decoration base layer.

Background technique

A very important point that distinguishes the architectural decoration industry technology from the traditional technology is the factory production of parts and components, and the prefabricated construction on the construction site. However, prefabricated construction is the prefabricated connection of parts and components to the original building through industrialized components. However, due to the different types and requirements of the original building base, it cannot fully meet the requirements of the architectural decoration industry technology. In addition, the architectural decoration industrial technology has specific requirements for the base of the original building, so the base treatment of the original building is an important part of the architectural decoration industrialization technology.

The prefabricated base of the building mainly achieves the following goals: quickly and accurately realize ground leveling, ground slope finding, ground height difference adjustment, wall leveling, buried pipeline, top leveling, and prefabricated installation interface settings.

At present, ground leveling, ground finding and ground leveling and ground height difference adjustment are mainly performed by wet cement mortar operation, which is not only difficult to control the leveling effect, but also requires high skills for operators. Time cost, and it is easy to cause secondary pollution to the completed decoration and affect the environment. For the pretreatment of the wall base layer, there are mainly two forms of wet leveling and dry leveling for different finishing materials. The wet leveling process is complicated, time-consuming and seriously pollutes the construction site; the dry leveling is mainly manifested in the keel veneer wall There are two kinds of materials: wood keel and light steel keel. The wood keel itself does not meet the requirements of fire protection regulations. It is necessary to carry out on-site secondary treatment such as fire prevention and anti-corrosion, and increase the process. It has the advantages of convenient and fast installation, relatively high degree of industrialization, and good leveling effect. However, the existing light steel keel is limited by its own size and specification, the installation structure is complicated, and the space for leveling the base layer is large, which is not suitable for small space use. The top surface is realized by expansion screws, suspension rods and various keels. Although it is a prefabricated construction, it requires on-site cutting and complicated installation procedures, and does not meet the existing requirements.

The reason is that in addition to the technical limitations of the above-mentioned basic treatment technology, at the same time in the traditional construction, the following problems occurred during the design plan stage, the deepening design stage, the material production and procurement stage, and the on-site construction stage:

1) Different units are often responsible for each stage of traditional decoration methods. Although there is unified management, the management level and depth are relatively shallow, and the integration of resources of each unit is low. Problems such as management, communication, and interests often lead to problems in each unit and each stage. It is difficult to connect and cooperate, it is difficult to distinguish between rights and responsibilities, and when problems arise, responsibilities are shifted to each other.

2) In the design stage, due to the lack of industry general modulus standards, the majority of non-standard parts need to be customized and processed on site. Materials such as cement mortar, light steel keel, and boom are all raw materials that are mixed on site, cut on site, and assembled. Therefore, the quality of the grassroots level and the utilization rate of materials are too dependent on the skills of the workers. At the same time, there is a lack of intermediate link inspections. It is easy to cause the owner to be dissatisfied with the quality of the decoration, resulting in rework or contradictions, which will lead to the owner's decoration cost. And the production and processing resources of the society cause great waste.

3) In the deepening design stage, due to the lack of standardized underlying technical system, deepening design specifications and support of deepening tools, the deepening quality of decoration projects is uneven, and different deepening schemes of the same design scheme are very different in terms of cost and construction difficulty. big difference.

4) In the material production and procurement stage, the procurement of building decoration materials and the processing of semi-finished products are still in the primary stage, and the processing of semi-finished products is usually completed on the construction site. This leads to high processing costs and serious material waste in material processing; uneven processing quality and lack of inspection standards.

5) The construction stage of the building decoration base is mainly on-site manual work and wet work. The cement mortar mixing, on-site plastering, grinding and other processes consume serious water resources, pollute the on-site environment, and bring harm to the health of on-site operators. At the same time, the construction quality is highly dependent on the skill proficiency of workers, and the overall level of construction efficiency is low due to the long wet operation time. Lead to longer construction period and material waste.

To sum up, the traditional grassroots processing system has problems such as difficult process management, difficult quality control, difficult subsequent upgrade, difficulty in improving efficiency, difficult system configuration, and difficulty in environmental protection due to the natural defects of manual and wet operation, and it is difficult to adapt to it. The development trend and trend of architectural decoration in the Internet era.

SUMMARY OF THE INVENTION

Based on this, it is necessary to address the technical problems of difficult process management, difficult quality control, difficult subsequent upgrades, difficult efficiency improvement, difficult system configuration, and difficult environmental protection due to the natural defects of manual and wet operation in the existing grassroots processing system. The invention provides an industrialized data processing method, electronic device and storage medium for building decoration base layer.

The invention provides an industrialized data processing method for a building decoration base layer, comprising:

In response to the user's call instruction, call the decorative base layer module data corresponding to the call command as the current decorative base layer module data, and the decorative base layer module data at least include the identity corresponding to the decorative base layer module data, And the material information corresponding to the decorative base module data;

Receive personalized configuration data about the current decorative base layer module data input by the user, the personalized configuration data at least include the material information corresponding to the personalized configuration data, and the current decorative base layer according to the personalized configuration data. The material information of the module data is modified to obtain the combined decoration base module data;

Calling the custom specification corresponding to the current decorative base module data as the current custom specification, verifying the combined decorative module data, and outputting a module data list if the combined decorative base module data satisfies the current custom specification and a bill of materials, wherein the module data list lists the identity identifiers corresponding to the current decorative base layer module data, and the bill of materials lists the material information corresponding to the combined decorative base layer module data.

Further, the decorative base layer module data includes: ground-level module data, top-level module data, and wall-level module data.

further more:

The ground level module data includes: wall corner load-bearing module data, ground leveling load-bearing module data, independent load-bearing leveling module data, wall corner leveling module data, or connection module data;

The top level module data includes: vertical leveling module data, top-mounted horizontal leveling structure module data, wall-mounted horizontal leveling structure module data, overall load-bearing module data, edge-receiving decoration module data, edge-receiving load-bearing module data, or Cantilever load-bearing module data;

The wall level module data includes: wall base leveling module data, wall base leveling connection module data, or local wall base leveling module data.

Further, the method also includes:

Send order information to the batching system, where the order information includes the module data list, the material list, and an order identifier related to the order information, and the batching system performs batching according to the module data list and the material list , and set factory code information on each component that is batched according to the material information of the combined decoration module data, receive the factory code information returned by the batching system, and combine the factory code information with the order identifier, and The identity association of the combined decoration module data corresponding to the component.

Further, after the order information is sent to the batching system, the order information includes the module data list, the material list, and an order identifier related to the order information, further including:

In response to the batching completion information returned by the batching system, assigning order information to the task allocation system, the order information including installation task information about each of the combined decorative base module data;

In response to the installation information acquisition request including the factory code information from the client, the associated order information and the corresponding combined decoration module data are determined according to the factory code information included in the installation information acquisition request, and the combined decoration corresponding to the factory code information is determined. The installation information of the module data is returned to the client. The invention provides an electronic device for data processing for the industrialization of building decoration base layers, comprising:

at least one processor; and,

a memory communicatively coupled to the at least one processor; wherein,

The memory stores instructions executable by the one processor, the instructions being executed by the at least one processor to enable the at least one processor to:

In response to the user's call instruction, call the decorative base layer module data corresponding to the call command as the current decorative base layer module data, and the decorative base layer module data at least include the identity corresponding to the decorative base layer module data, And the material information corresponding to the decorative base module data;

Receive personalized configuration data about the current decorative base layer module data input by the user, the personalized configuration data at least include the material information corresponding to the personalized configuration data, and the current decorative base layer according to the personalized configuration data. The material information of the module data is modified to obtain the combined decoration base module data;

Calling the custom specification corresponding to the current decorative base module data as the current custom specification, verifying the combined decorative module data, and outputting a module data list if the combined decorative base module data satisfies the current custom specification and a bill of materials, wherein the module data list lists the identity identifiers corresponding to the current decorative base layer module data, and the bill of materials lists the material information corresponding to the combined decorative base layer module data.

Further, the decorative base layer module data includes: ground-level module data, top-level module data, and wall-level module data.

further more:

The ground level module data includes: wall corner load-bearing module data, ground leveling load-bearing module data, independent load-bearing leveling module data, wall corner leveling module data, or connection module data;

The top level module data includes: vertical leveling module data, top-mounted horizontal leveling structure module data, wall-mounted horizontal leveling structure module data, overall load-bearing module data, edge-receiving decoration module data, edge-receiving load-bearing module data, or Cantilever load-bearing module data;

The wall level module data includes: wall base leveling module data, wall base leveling connection module data, or local wall base leveling module data.

Further, the processor can also:

Send order information to the batching system, where the order information includes the module data list, the material list, and an order identifier related to the order information, and the batching system performs batching according to the module data list and the material list , and set factory code information on each component that is batched according to the material information of the combined decoration module data, receive the factory code information returned by the batching system, and combine the factory code information with the order identifier, and The identity association of the combined decoration module data corresponding to the component.

Further, after the order information is sent to the batching system, the order information includes the module data list, the material list, and an order identifier related to the order information, further including:

In response to the batching completion information returned by the batching system, assigning order information to the task allocation system, the order information including installation task information about each of the combined decorative base module data;

In response to the installation information acquisition request including the factory code information from the client, the associated order information and the corresponding combined decoration module data are determined according to the factory code information included in the installation information acquisition request, and the combined decoration corresponding to the factory code information is determined. The installation information of the module data is returned to the client.

The present invention provides a storage medium, which stores computer instructions, and when the computer executes the computer instructions, is used to execute all steps of the aforementioned industrialized data processing method for a building decoration base layer.

The invention takes the modularization of architectural decoration parts as the core, the industrialized organization of production as the basis, and the on-site assembly construction as the means to realize a new assembly-type basic system that adapts to the industrialization of the Internet era. The present invention innovates the traditional multi-unit building decoration method through the modular data design into an information-based design, procurement, and construction integrated management mode with coding and module data as the core. The process is managed and controlled in a unified manner, and quality problems can be accurately traced, avoiding the problems of unclear rights and responsibilities and low communication efficiency. At the same time, by innovating the traditional grass-roots treatment construction process, replacing the traditional wet method, taking advantage of the "modular" design, through the standard modular modular data design and unified data platform information integration, the traditional on-site manual work The transformation of processing operations into unified industrialized production at the back end not only improves production efficiency, but also improves material utilization, quality of parts, and reduces on-site pollution and construction waste. Through the detailed definition and design of the module data, the present invention formulates a unified and standardized underlying technical system, in-depth design specifications and in-depth tools, so that the scheme designer and the in-depth designer can make full use of the advantages of the Internet, and the design and in-depth can be used locally or in the cloud. The tool (software end) is used to design the architectural decoration scheme matching decoration module data and functional module data, and can use the integrated and systematic solution to meet the decoration and functional requirements of different indoor and outdoor spaces. The invention reduces the dependence of building decoration operations on skilled workers through coding information guidance, prefabricated installation methods, and systematic installation guidance training, and transforms the traditional "multiple types of construction" into "installers" as the main manpower The resource model can help solve the increasingly serious problem of "labor shortage" in the industry, while greatly shortening the total construction period of building decoration projects, and improving the efficiency of unit labor. Finally, through the natural advantages of prefabricated module data, the present invention can easily complete the secondary renovation and functional iterative upgrade of the base layer, recycle, process and recycle the replaced and upgraded module data, and at the same time, it is very convenient to realize the internal equipment pipeline. Maintenance greatly reduces the waste of building decoration materials, which is of great significance to the resource conservation and green sustainable development of the whole industry.

Description of drawings

Fig. 1 is the working flow chart of a kind of industrialized data processing method of building decoration base layer of the present invention;

2 is a schematic diagram of the hardware structure of an electronic device used for data processing in the industrialization of building decoration base layers of the present invention;

3 is a schematic diagram of communication connection between an electronic device, a batching system and a task distribution system according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of components corresponding to data of a decorative base layer module according to an embodiment of the present invention.

Detailed ways

The present invention will be described in further detail below with reference to the accompanying drawings and specific embodiments.

As shown in Figure 1, it is the working flow chart of a kind of industrialized data processing method of building decoration base layer of the present invention, including:

Step S101, in response to a user's fetching instruction, fetching the decorative base layer module data corresponding to the fetching instruction as the current decorative base layer module data, and the decorative base layer module data at least includes the data corresponding to the decorative base layer module data. Identity identification, and the material information corresponding to the decorative base module data;

Step S102, receiving personalized configuration data about the current decorative base layer module data input by the user, the personalized configuration data at least includes the material information corresponding to the personalized configuration data, and according to the personalized configuration data. Modify the material information of the current decorative base module data to obtain the combined decorative base module data;

Step S103, call the custom specification corresponding to the current decoration base module data as the current customization specification, verify the combined decoration module data, and output if the combined decoration base module data satisfies the current custom specification A module data list and a bill of materials, wherein the module data list lists the identity identifiers corresponding to the current decorative base layer module data, and the material list lists the materials corresponding to the combined decorative base layer module data information.

Specifically, a large amount of decorative base module data can be pre-stored in the database. The modular design method is adopted for the decorative base module data, and the standard module data of different modules is selected according to different spaces and parts. The module data should be able to meet the functions of assembly, operation and maintenance replacement, and technology upgrade and replacement. The data of each decorative base module corresponds to certain material information. By simply correcting the module data in the structure and installation method, the space size deviation and the space non-standard building module are compensated. When designing, it is necessary to select different types and different modules of space-level module data according to different functional spaces and design requirements. The above various structural module data, combined with the systematic building module, constitute the module database of the prefabricated basic system. The module database of the building prefabricated basic system is constructed and managed by means of a computer database. The composition of this module database includes information such as the coding of the module data, drawings (two-dimensional and three-dimensional), design and customization specifications; this module database can be used locally. It can be stored and called in the form of cloud storage or cloud storage, and new module data can be continuously developed to update and iterate the module database.

Then, the scheme designer or the detailing designer can select the module data of the calling module database locally or in the cloud according to the specific scene and requirements, thereby triggering step S101 to call the decorative base module data from the database.

The scheme designer or detailing designer can complete the personalized configuration of the design scheme in the form of computer assistance (including but not limited to tools such as computer, IPAD, mobile phone, or software and APP, etc.), and generate personalized configuration data, thereby triggering step S102 . Step S103 is then executed to determine whether the customization rules are met, and if so, generate and output the BOM (material) module data list and bill of materials that can be automatically generated for the industrialized organization for production use by the factory organization. Custom rules are associated with each module data and need to satisfy the modulus rules of the module data, as well as the modulus rules of the entire building.

The invention takes the modularization of architectural decoration parts as the core, the industrialized organization of production as the basis, and the on-site assembly construction as the means to realize a new assembly-type basic system that adapts to the industrialization of the Internet era.

In one embodiment, the decorative base layer module data includes: ground level module data, top surface level module data, and wall level module data.

In this embodiment, the module data of the prefabricated base system is decomposed layer by layer to form the module data of the ground level, the top level, and the wall level.

In one of the embodiments:

The ground level module data includes: wall corner load-bearing module data, ground leveling load-bearing module data, independent load-bearing leveling module data, wall corner leveling module data, or connection module data;

The top level module data includes: vertical leveling module data, top-mounted horizontal leveling structure module data, wall-mounted horizontal leveling structure module data, overall load-bearing module data, edge-receiving decoration module data, edge-receiving load-bearing module data, or Cantilever load-bearing module data;

The wall level module data includes: wall base leveling module data, wall base leveling connection module data, or local wall base leveling module data.

The module data at the ground level is mainly composed of the module data at the component level. It is a series of module data set in combination with specific space requirements, mainly including: corner load-bearing module data, ground leveling load-bearing module data, independent load-bearing adjustment Leveling module data, corner leveling module data, connection module data, etc.

The module data of the top level is mainly composed of the module data of its parts level, which is a series of module data set in combination with specific space requirements, mainly including: vertical leveling module data, top-mounted horizontal leveling structure, wall-mounted Horizontal leveling structure, overall load-bearing module data, edge trimming module data, edge-closing load-bearing module data and cantilever load-bearing module data, etc.

The module data at the wall level is mainly composed of the module data at the component level. It is a series of module data set in combination with specific space requirements, mainly including: wall base leveling module data, wall base leveling connection module data , local wall base leveling module data, etc.

As an example, Fig. 4 shows the component 41 corresponding to the data of the ground leveling load-bearing module.

In one embodiment, the method further includes:

Send order information to the batching system, where the order information includes the module data list, the material list, and an order identifier related to the order information, and the batching system performs batching according to the module data list and the material list , and set factory code information on each component that is batched according to the material information of the combined decoration module data, receive the factory code information returned by the batching system, and combine the factory code information with the order identifier, and The identity association of the combined decoration module data corresponding to the component.

Specifically, the project order is processed through the background database in the form of a BOM (material) list, and the material demand information of various module data (codes) is sent to the factory's batching system, and the factory is unified according to the material demand information (code). Purchasing, scheduling production and secondary processing, production and processing are completed in the form of automatic assembly line operations, and unified storage and logistics distribution to each central warehouse based on order information (code), all completed parts have codes for scanning The identification code information (RIDF radio frequency method or two-dimensional bar code method), the code information can be scanned to obtain the corresponding order information, production information and installation information.

In one embodiment, after the sending order information to the batching system, the order information includes the module data list, the material list, and an order identifier related to the order information, further including:

In response to the batching completion information returned by the batching system, assigning order information to the task allocation system, the order information including installation task information about each of the combined decorative base module data;

In response to the installation information acquisition request including the factory code information from the client, the associated order information and the corresponding combined decoration module data are determined according to the factory code information included in the installation information acquisition request, and the combined decoration corresponding to the factory code information is determined. The installation information of the module data is returned to the client.

Specifically, each certified installation group (a social construction installation team that has been trained and certified by the industrial task distribution system) obtains order information from the task distribution system, receives and confirms the installation task according to the order information, and informs the logistics to deliver to the construction site for installation. Construction work.

The prefabricated construction is implemented as follows:

First, scan and lay out the construction site accurately through an infrared scanner (hand-held or pedestal type) to determine the installation guide lines and completed surface lines of each block of the entire space. According to the completed installation guide lines, first complete the wall system The wall base leveling module, the wall base leveling connection module, the local wall base leveling module, etc.

Secondly, complete the installation of vertical leveling module, top-mounted horizontal leveling module, wall-mounted horizontal leveling module, integral load-bearing module, edge-receiving decorative load-bearing module, edge-receiving load-bearing module and cantilever load-bearing module of the top system through the hand-held installation tool;

Finally, complete the installation of the corner load-bearing module, ground leveling load-bearing module, independent load-bearing leveling module, corner leveling module and connection module of the ground system.

Figure 2 is a schematic diagram of the hardware structure of an electronic device 1 used for data processing in the industrialization of building decoration base layers of the present invention, including:

at least one processor 201; and,

a memory 202 in communication with the at least one processor 201; wherein,

The memory 202 stores instructions executable by the one processor, the instructions being executed by the at least one processor to enable the at least one processor to:

In response to the user's call instruction, call the decorative base layer module data corresponding to the call command as the current decorative base layer module data, and the decorative base layer module data at least include the identity corresponding to the decorative base layer module data, And the material information corresponding to the decorative base module data;

Receive personalized configuration data about the current decorative base layer module data input by the user, the personalized configuration data at least include the material information corresponding to the personalized configuration data, and the current decorative base layer according to the personalized configuration data. The material information of the module data is modified to obtain the combined decoration base module data;

Calling the custom specification corresponding to the current decorative base module data as the current custom specification, verifying the combined decorative module data, and outputting a module data list if the combined decorative base module data satisfies the current custom specification and a bill of materials, wherein the module data list lists the identity identifiers corresponding to the current decorative base layer module data, and the bill of materials lists the material information corresponding to the combined decorative base layer module data.

A processor 202 is taken as an example in FIG. 2 .

The server may also include: an input device 203 and an output device 204 .

The processor 201, the memory 202, the input device 203, and the display device 204 may be connected through a bus or in other ways, and the connection through a bus is taken as an example in the figure.

As a non-volatile computer-readable storage medium, the memory 202 can be used to store non-volatile software programs, non-volatile computer-executable programs and module data, such as the industrialized data of the architectural decoration base layer in the embodiments of the present application. The program instruction/module data corresponding to the processing method, for example, the method flow shown in FIG. 1 . The processor 201 executes various functional applications and data processing by running the non-volatile software programs, instructions and module data stored in the memory 202, that is, the data processing method for realizing the industrialization of the building decoration base layer in the above embodiment.

The memory 202 can include a stored program area and a stored data area, wherein the stored program area can store an operating system, an application program required by at least one function; data etc. Additionally, memory 202 may include high-speed random access memory, and may also include non-volatile memory, such as at least one magnetic disk storage device, flash memory device, or other non-volatile solid state storage device. In some embodiments, the memory 202 may optionally include memory located remotely relative to the processor 201, and the remote memory may be connected to the apparatus for performing the data processing method for the industrialization of the building decoration base layer through a network. Examples of such networks include, but are not limited to, the Internet, an intranet, a local area network, a mobile communication network, and combinations thereof.

The input device 203 can receive input user clicks, and generate signal input related to user settings and function control of the data processing method for the industrialization of building decoration base layers. The display device 204 may include a display device such as a display screen.

The one or more module data is stored in the memory 202, and when executed by the one or more processors 201, the data processing method for the industrialization of the building decoration base layer in any of the above method embodiments is executed.

In one embodiment, the decorative base layer module data includes: ground level module data, top surface level module data, and wall level module data.

In one of the embodiments:

The ground level module data includes: wall corner load-bearing module data, ground leveling load-bearing module data, independent load-bearing leveling module data, wall corner leveling module data, or connection module data;

The top level module data includes: vertical leveling module data, top-mounted horizontal leveling structure module data, wall-mounted horizontal leveling structure module data, overall load-bearing module data, edge-receiving decoration module data, edge-receiving load-bearing module data, or Cantilever load-bearing module data;

The wall level module data includes: wall base leveling module data, wall base leveling connection module data, or local wall base leveling module data.

In one of the embodiments, the processor can further:

Send order information to the batching system, where the order information includes the module data list, the material list, and an order identifier related to the order information, and the batching system performs batching according to the module data list and the material list , and set factory code information on each component that is batched according to the material information of the combined decoration module data, receive the factory code information returned by the batching system, and combine the factory code information with the order identifier, and The identity association of the combined decoration module data corresponding to the component.

In one embodiment, after the sending order information to the batching system, the order information includes the module data list, the material list, and an order identifier related to the order information, further including:

In response to the batching completion information returned by the batching system, assigning order information to the task allocation system, the order information including installation task information about each of the combined decorative base module data;

In response to the installation information acquisition request including the factory code information from the client, the associated order information and the corresponding combined decoration module data are determined according to the factory code information included in the installation information acquisition request, and the combined decoration corresponding to the factory code information is determined. The installation information of the module data is returned to the client.

As shown in FIG. 3 , in one embodiment, the electronic device 1 of the present invention is connected in communication with the batching system 2 , the task distribution system 3 and the client 4 .

The present invention provides a storage medium, which stores computer instructions, and when the computer executes the computer instructions, is used to execute all steps of the aforementioned industrialized data processing method for a building decoration base layer.

The above-mentioned embodiments only represent several embodiments of the present invention, and the descriptions thereof are specific and detailed, but should not be construed as a limitation on the scope of the patent of the present invention. It should be pointed out that for those of ordinary skill in the art, without departing from the concept of the present invention, several modifications and improvements can also be made, which all belong to the protection scope of the present invention. Therefore, the protection scope of the patent of the present invention should be subject to the appended claims.

Claims (11)

1. an industrialized data processing method for building decoration base layer, is characterized in that, comprises: In response to the user's call instruction, call the decorative base layer module data corresponding to the call command as the current decorative base layer module data, and the decorative base layer module data at least include the identity corresponding to the decorative base layer module data, And the material information corresponding to the decorative base module data; Receive personalized configuration data about the current decorative base layer module data input by the user, the personalized configuration data at least include the material information corresponding to the personalized configuration data, and the current decorative base layer according to the personalized configuration data. The material information of the module data is modified to obtain the combined decoration base module data; Calling the custom specification corresponding to the current decorative base module data as the current custom specification, verifying the combined decorative module data, and outputting a module data list if the combined decorative base module data satisfies the current custom specification and a bill of materials, wherein the module data list lists the identity identifiers corresponding to the current decorative base layer module data, and the bill of materials lists the material information corresponding to the combined decorative base layer module data. 2 . The industrialized data processing method for building decoration base level according to claim 1 , wherein the decoration base level module data comprises: ground level module data, top level module data, and wall level module data. 3 . 3. building decoration base layer industrialized data processing method according to claim 2, is characterized in that: The ground level module data includes: wall corner load-bearing module data, ground leveling load-bearing module data, independent load-bearing leveling module data, wall corner leveling module data, or connection module data; The top level module data includes: vertical leveling module data, top-mounted horizontal leveling structure module data, wall-mounted horizontal leveling structure module data, overall load-bearing module data, edge-receiving decoration module data, edge-receiving load-bearing module data, or Cantilever load-bearing module data; The wall level module data includes: wall base leveling module data, wall base leveling connection module data, or local wall base leveling module data. 4. The industrialized data processing method for building decoration base layer according to claim 1, wherein the method further comprises: Send order information to the batching system, where the order information includes the module data list, the material list, and an order identifier related to the order information, and the batching system performs batching according to the module data list and the material list , and set factory code information on each component that is batched according to the material information of the combined decoration module data, receive the factory code information returned by the batching system, and combine the factory code information with the order identifier, and The identity association of the combined decoration module data corresponding to the component. 5. The industrialized data processing method for building decoration base layer according to claim 4, characterized in that, in the sending order information to the batching system, the order information includes the module data list, the material list, and information about all After the order identifier of the order information, it also includes: In response to the batching completion information returned by the batching system, assigning order information to the task allocation system, the order information including installation task information about each of the combined decorative base module data; In response to the installation information acquisition request including the factory code information from the client, the associated order information and the corresponding combined decoration module data are determined according to the factory code information included in the installation information acquisition request, and the combined decoration corresponding to the factory code information is determined. The installation information of the module data is returned to the client. 6. An electronic device for data processing of building decoration base layer industrialization, characterized in that, comprising: at least one processor; and, a memory communicatively coupled to the at least one processor; wherein, The memory stores instructions executable by the one processor, the instructions being executed by the at least one processor to enable the at least one processor to: In response to the user's call instruction, call the decorative base layer module data corresponding to the call command as the current decorative base layer module data, and the decorative base layer module data at least include the identity corresponding to the decorative base layer module data, And the material information corresponding to the decorative base module data; Receive personalized configuration data about the current decorative base layer module data input by the user, the personalized configuration data at least include the material information corresponding to the personalized configuration data, and the current decorative base layer according to the personalized configuration data. The material information of the module data is modified to obtain the combined decoration base module data; Calling the custom specification corresponding to the current decorative base module data as the current custom specification, verifying the combined decorative module data, and outputting a module data list if the combined decorative base module data satisfies the current custom specification and a bill of materials, wherein the module data list lists the identity identifiers corresponding to the current decorative base layer module data, and the bill of materials lists the material information corresponding to the combined decorative base layer module data. 7 . The electronic device according to claim 6 , wherein the decorative base level module data comprises: ground level module data, top surface level module data, and wall level module data. 8 . 8. The electronic device according to claim 7, wherein: The ground level module data includes: wall corner load-bearing module data, ground leveling load-bearing module data, independent load-bearing leveling module data, wall corner leveling module data, or connection module data; The top level module data includes: vertical leveling module data, top-mounted horizontal leveling structure module data, wall-mounted horizontal leveling structure module data, overall load-bearing module data, edge-receiving decoration module data, edge-receiving load-bearing module data, or Cantilever load-bearing module data; The wall level module data includes: wall base leveling module data, wall base leveling connection module data, or local wall base leveling module data. 9. The electronic device according to claim 6, wherein the processor is further capable of: Send order information to the batching system, where the order information includes the module data list, the material list, and an order identifier related to the order information, and the batching system performs batching according to the module data list and the material list , and set factory code information on each component that is batched according to the material information of the combined decoration module data, receive the factory code information returned by the batching system, and combine the factory code information with the order identifier, and The identity association of the combined decoration module data corresponding to the component. 10 . The electronic device according to claim 9 , wherein, in the sending of order information to the batching system, the order information includes the module data list, the material list, and an order related to the order information. 11 . After the identification, it also includes: In response to the batching completion information returned by the batching system, assigning order information to the task allocation system, the order information including installation task information about each of the combined decorative base module data; In response to the installation information acquisition request including the factory code information from the client, the associated order information and the corresponding combined decoration module data are determined according to the factory code information included in the installation information acquisition request, and the combined decoration corresponding to the factory code information is determined. The installation information of the module data is returned to the client. 11. A storage medium, characterized in that the storage medium stores computer instructions, and when a computer executes the computer instructions, it is used to execute the industrialized data processing method for a building decoration base layer according to any one of claims 1 to 5. all steps.