CN116579073A - Modeling method based on interscan Smart3D - Google Patents

Abstract

The application relates to a modeling method based on an interscan Smart3D, which defines space types with different characteristics in a three-dimensional modeling environment of the interscan Smart3D; defining the space attribute of each type of space; carrying out space region division on the spaces of all the attributes to obtain application spaces under all the attribute spaces; inputting the entity model of the ship into a corresponding application space, performing attribute check on the attribute value of the entity model, and generating a required entity model and corresponding check data. By creating virtual spaces with different characteristics and combining the entity models and data rules, entity models which do not meet the requirements are found out early, and entity model quantity information of the space area is counted. The required model and check data are acquired, so that more complicated data analysis work which cannot be completed on the entity model is completed, and various wide applications based on the model are realized.

Description

Modeling method based on interscan Smart3D

Technical Field

The disclosure relates to the technical field of ships, in particular to an interscan Smart 3D-based modeling method, device and control system.

Background

Modeling is usually performed based on a solid model, and what is seen is obtained; the spatial division is also based on solid model boundaries. For more complex models, analysis work of large data is required, so the created model needs to be convenient for supporting convenience processing and operation of the data.

However, the solid models in the existing design are scattered, a unique individual with certain characteristics cannot be formed, the relevance among the part models is insufficient, and each model data is isolated and is insufficient to support the analysis and operation of the model data.

In a ship production system, space modeling involved in a ship is more complex for building a ship three-dimensional model, the number of models of each project is more, and technical requirements and data types of each model may have larger differences. Therefore, for complex ships, various space regions in the ship have different characteristics and technical requirements, and it is difficult to distinguish the different characteristics and technical requirements through the existing solid model.

Disclosure of Invention

In order to solve the problems, the application provides an modeling method, device and control system based on an interscan Smart 3D.

In one aspect of the application, a modeling method based on an interscan Smart3D is provided, which comprises the following steps:

defining space types with different characteristics in an interscan Smart3D three-dimensional modeling environment;

defining the space attribute of each type of space;

carrying out space region division on the spaces of all the attributes to obtain application spaces under all the attribute spaces;

inputting the entity model of the ship into a corresponding application space, performing attribute check on the attribute value of the entity model, and generating a required entity model and corresponding check data.

As an alternative embodiment of the present application, optionally, defining spatial types of different characteristics in the three-dimensional modeling environment of the interscan Smart3D includes:

defining a plurality of different ship areas according to ship design information;

defining space types corresponding to each ship region in the three-dimensional modeling space of the inter Smart3D according to the defined ship region, and generating a space type file under the space where each ship region is located;

and uploading and storing the space type files corresponding to the ship areas.

As an optional embodiment of the present application, optionally, spatial attribute definition is performed for each type of space, including:

acquiring a space type file of each ship area;

setting attribute conditions for the space type files of each ship area according to the attribute of each ship area, and generating space attribute files under each space type file;

uploading and storing space attribute files corresponding to each ship area;

wherein the attribute conditions include: basic attributes and unique attributes;

the basic attribute is set according to the definition number and the definition name;

and setting unique attributes according to the basic attributes of each ship area.

As an optional embodiment of the present application, optionally, space region division is performed on each attribute space to obtain an application space under each attribute space, including:

presetting a region dividing rule;

acquiring a space attribute file of each ship region, dividing the space region of each ship region according to a region division rule, and generating a space division sub-file under each space attribute file;

and transmitting and storing the space division subfiles corresponding to the ship areas.

As an optional implementation manner of the present application, optionally, inputting the physical model of the ship into a corresponding application space, performing attribute checking on the attribute value of the physical model, and generating the required physical model and corresponding checking data, including:

inputting a ship entity model to an interscan Smart3D;

analyzing and acquiring basic information of a ship entity model, and placing the ship entity model into a corresponding space division sub-file according to the basic information of the ship entity model;

and carrying out attribute check on the attribute values of the ship entity model according to the space division sub-file and the inherent attribute values of the related upper files, and generating the required entity model and corresponding check data.

As an optional embodiment of the present application, optionally, performing attribute verification on an attribute value of a ship entity model according to the intrinsic attribute value of the space division sub-file and an associated upper file, and generating a required entity model and corresponding verification data, including:

acquiring attribute values of a ship entity model;

comparing the intrinsic attribute value configured on the current space division sub-file with the attribute value of the ship entity model, and judging whether the attribute value of the ship entity model is matched with the intrinsic attribute value configured on the space division sub-file;

if the model quantity information is matched with the model quantity information of the ship entity model, counting and outputting the model quantity information of the ship entity model;

if the model quantity information is not matched with the model quantity information, correcting the attribute value of the ship entity model according to the requirement, and outputting the corrected model quantity information and corresponding checking data of the ship entity model.

As an optional implementation manner of the present application, optionally, after comparing and checking the intrinsic attribute value configured on the current space division subfile with the attribute value of the ship entity model, the method further includes:

comparing the intrinsic attribute value configured on the spatial attribute file of the previous stage of the current spatial division sub-file with the attribute value of the ship entity model, and judging whether the attribute value of the ship entity model is matched with the intrinsic attribute value configured on the spatial attribute file;

if the model quantity information is matched with the model quantity information of the ship entity model, counting and outputting the model quantity information of the ship entity model;

if the model quantity information is not matched with the model quantity information, correcting the attribute value of the ship entity model according to the requirement, and outputting the corrected model quantity information and corresponding checking data of the ship entity model.

As an optional embodiment of the present application, optionally, after comparing and checking the intrinsic attribute value configured on the spatial attribute file with the attribute value of the ship entity model, the method further includes:

comparing the inherent attribute value configured on the space type file of the previous stage of the current space attribute file with the attribute value of the ship entity model, and judging whether the attribute value of the ship entity model is matched with the inherent attribute value configured on the space attribute file;

if the model quantity information is matched with the model quantity information of the ship entity model, counting and outputting the model quantity information of the ship entity model;

if the model quantity information is not matched with the model quantity information, correcting the attribute value of the ship entity model according to the requirement, and outputting the corrected model quantity information and corresponding checking data of the ship entity model.

In another aspect of the present application, an apparatus is provided for implementing the modeling method based on the interscan Smart3D, including:

the space type definition module is used for defining space types with different characteristics in the three-dimensional modeling environment of the inter Smart3D;

the space attribute definition module is used for defining the space attribute of each type of space;

the space region dividing module is used for dividing the space of each attribute to obtain application spaces under each attribute space;

and the entity model checking module is used for inputting the entity model of the ship into the corresponding application space, checking the attribute of the entity model attribute value, and generating the required entity model and corresponding checking data.

In another aspect of the present application, a base control system is also provided, including:

a processor;

a memory for storing processor-executable instructions;

wherein the processor is configured to implement the inter-graph Smart 3D-based modeling method when executing the executable instructions.

The application has the technical effects that:

according to the application, space types with different characteristics are defined in an interscan Smart3D three-dimensional modeling environment; defining the space attribute of each type of space; carrying out space region division on the spaces of all the attributes to obtain application spaces under all the attribute spaces; inputting the entity model of the ship into a corresponding application space, performing attribute check on the attribute value of the entity model, and generating a required entity model and corresponding check data. A series of space three-dimensional virtual models with different characteristics are established through customization and attribute definition of the models, unique attributes and technical requirements are given to the space three-dimensional virtual models, inherent attributes and technical requirements of the space three-dimensional virtual models are compared with the attributes of the entity models through collection of entity model data in the space three-dimensional virtual models, entity model object quantity information of the space region can be counted by early finding out entity models which do not meet the requirements. By creating a space three-dimensional virtual model with different characteristics and combining the entity model and the data rule, the required model and check data are obtained, so that more complicated data analysis work which cannot be completed by the entity model is completed, and various wide applications based on the model are realized.

Other features and aspects of the present disclosure will become apparent from the following detailed description of exemplary embodiments, which proceeds with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate exemplary embodiments, features and aspects of the present disclosure and together with the description, serve to explain the principles of the disclosure.

FIG. 1 is a schematic flow chart of an implementation of an interscan Smart 3D-based modeling method of the present application;

FIG. 2 shows a definition table for the spatial types of the present application;

FIG. 3 shows a definition table for the spatial attributes of the present application;

FIG. 4 shows a schematic view of the various levels of directories for the Z-finished area of the present application.

Detailed Description

Various exemplary embodiments, features and aspects of the disclosure will be described in detail below with reference to the drawings. In the drawings, like reference numbers indicate identical or functionally similar elements. Although various aspects of the embodiments are illustrated in the accompanying drawings, the drawings are not necessarily drawn to scale unless specifically indicated.

The word "exemplary" is used herein to mean "serving as an example, embodiment, or illustration. Any embodiment described herein as "exemplary" is not necessarily to be construed as preferred or advantageous over other embodiments.

In addition, numerous specific details are set forth in the following detailed description in order to provide a better understanding of the present disclosure. It will be understood by those skilled in the art that the present disclosure may be practiced without some of these specific details. In some instances, methods, means, elements, and circuits well known to those skilled in the art have not been described in detail in order not to obscure the present disclosure.

Example 1

As shown in fig. 1, in one aspect of the present application, a modeling method based on an interscan Smart3D is provided, which includes the following steps:

s1, defining space types with different characteristics in an interscan Smart3D three-dimensional modeling environment;

s2, defining spatial attributes of the spaces of each type;

s3, dividing the space of each attribute into space regions to obtain application spaces under each attribute space;

s4, inputting the entity model of the ship into a corresponding application space, performing attribute check on the attribute value of the entity model, and generating a required entity model and corresponding check data.

The application describes a novel modeling method based on an interscan Smart3D, and various extensive applications based on the model are realized through customization and attribute definition of the model. And creating a space three-dimensional virtual model with different characteristics, and acquiring required model and check data by combining the entity model and the data rule, thereby completing more complicated data analysis work which cannot be completed by the entity model.

In the specific implementation, a series of space three-dimensional virtual models with different characteristics are established, unique attributes and technical requirements are given to the space three-dimensional virtual models, the inherent attributes and the technical requirements of the space three-dimensional virtual models are compared with the attributes of the entity models by collecting the entity model data in the space three-dimensional virtual models, the entity models which do not meet the requirements can be found out early, and the entity model quantity information of the space area can be counted for production dispatching and stage finishing.

In this embodiment, the functions of the interscan Smart3D are not described here.

The scheme is generally divided into: space type division in an inter Smart3D modeling space, attribute division under each space type, space region division under each attribute space, and finally entity model construction or model matching in the divided application space.

Each step correspondingly generates a respective space modeling file which is a space type file, a space attribute file and a space division sub-file, and the entity model is applied to the subspace generated by the space division sub-file.

In each file, when the setting is divided, the unique attribute, such as attribute value, type, identifier, etc. of the space type, is configured for the file, and the space attribute file is configured with attribute symbol, attribute value, etc., specifically, the space attribute file is configured by a designer. When the ship design is specifically performed, the attribute values of the space application layers are specifically and correspondingly set.

The generated ship entity model is input into the corresponding subspace, the type, attribute and the like of the space of the entity model can be identified and judged according to the upper and lower space file catalogues of the subspace, the entity model which does not meet the requirements can be found in time, and the entity model quantity information of the space region can be counted.

In brief, in the three-dimensional modeling environment of the inter Smart3D, modeling space environments with different characteristics are defined, and the modeling space environments are correspondingly divided into different types of modeling spaces according to different characteristics of ships, wherein next-stage space application layers with different attributes are arranged below each space, and next-stage space application layers with different division areas are arranged below each space. The spatial attribute files of different application layers are configured with attribute values to generate corresponding spatial layer files. For example, the type space where the ship finishing area BOX is located is divided into the part modeling space under the respective attributes according to the basic attribute and the unique attribute of the finishing area, and then the space division is performed on each part modeling space.

The principle of implementation of the above steps will be specifically described below.

As an alternative embodiment of the present application, optionally, defining spatial types of different characteristics in the three-dimensional modeling environment of the interscan Smart3D includes:

defining a plurality of different ship areas according to ship design information;

defining space types corresponding to each ship region in the three-dimensional modeling space of the inter Smart3D according to the defined ship region, and generating a space type file under the space where each ship region is located;

and uploading and storing the space type files corresponding to the ship areas.

As shown in fig. 2, the present embodiment defines a plurality of different ship areas, mainly a finishing area, a safe return area, a pipe material selection limiting area, and the like, according to ship design information. In the process of coating design, the explanation of the regional division name and the space definition of each ship region is designed with easy reference to drawings.

And entering an modeling space of the inter Smart3D, dividing according to the types of the ship regions, and correspondingly dividing a plurality of modeling application spaces of the corresponding ship region types in the modeling space of the inter Smart 3D. After the building, the space type files corresponding to the ship areas are obtained by storing. And entering a space type file corresponding to each ship region of different types, and entering a modeling space of the ship region.

In the modeling space of each type of ship region, the first-level subspace (attribute space under the ship region) under each modeling space can be continuously built by referring to the principle, the next-level subspace (region division subspace) under the attribute space is related to each other between the upper-level file and the lower-level file, so that the first-level modeling space under each ship region and the corresponding second-level modeling space are conveniently divided in a space hierarchy manner.

As an optional embodiment of the present application, optionally, spatial attribute definition is performed for each type of space, including:

acquiring a space type file of each ship area;

setting attribute conditions for the space type files of each ship area according to the attribute of each ship area, and generating space attribute files under each space type file;

uploading and storing space attribute files corresponding to each ship area;

wherein the attribute conditions include: basic attributes and unique attributes;

the basic attribute is set according to the definition number and the definition name;

and setting unique attributes according to the basic attributes of each ship area.

As shown in fig. 3, under the space type file, each attribute of the ship region is divided into application spaces of the next stage. For example, in the modeling space of the ship area A, a space attribute file of the next stage is established according to the basic attribute and the unique attribute of the ship area A. For example, in the space of the finished-area BOX, a basic attribute space such as a cabin and an air conditioning station is established according to the basic attribute of the finished-area BOX, and a unique attribute space of the finished-area BOX is established according to the bottom deck layer and the like of the finished-area BOX. The components of the finished region BOX of different attributes will complete the corresponding base attribute space and unique attribute space under the space of the finished region BOX. Each established space is provided with independent configuration parameters and attribute values, when a model is established or input, the inherent attribute values of each application layer are used for restraining the established model, or the attribute values of the input entity model are judged, if the entity model is found to be not matched with the inherent attribute values of the current space, judging information is directly output.

In this embodiment, the spatial attribute file mainly includes the following aspects:

a safe return area BOX attribute space;

tube material confinement region BOX attribute space;

tank zone BOX attribute space;

a damaged area BOX attribute space;

a specific region BOX attribute space;

wet zone BOX attribute space;

the space BOX attribute space is restricted.

After the division according to the attributes, subdivision is performed, for example, in the unique attribute space of the BOX of the built-up area of the bottom deck layer, a secondary space of the bottom deck layer is built for application modeling of the parts of the bottom deck layer.

As an optional embodiment of the present application, optionally, space region division is performed on each attribute space to obtain an application space under each attribute space, including:

presetting a region dividing rule;

acquiring a space attribute file of each ship region, dividing the space region of each ship region according to a region division rule, and generating a space division sub-file under each space attribute file;

and transmitting and storing the space division subfiles corresponding to the ship areas.

The principle can be seen from the above-mentioned attribute space, etc.

As an optional implementation manner of the present application, optionally, inputting the physical model of the ship into a corresponding application space, performing attribute checking on the attribute value of the physical model, and generating the required physical model and corresponding checking data, including:

inputting a ship entity model to an interscan Smart3D;

analyzing and acquiring basic information of a ship entity model, and placing the ship entity model into a corresponding space division sub-file according to the basic information of the ship entity model;

and carrying out attribute check on the attribute values of the ship entity model according to the space division sub-file and the inherent attribute values of the related upper files, and generating the required entity model and corresponding check data.

When the space application layer is divided, space files of ship modeling at each level are obtained, modeling space layer files and attributes of different ship areas can be obtained in the inter Smart3D, and attribute values of the application space files at each level, such as space application configuration parameters, layers and the like, can be obtained through the inter Smart 3D.

The various levels of directories in the Z-finished zone, as shown in FIG. 4, are the finishing data for the Z-finished zone. And the data can be used for the solid modeling of the Z finished region or the verification and correction of the solid model of the Z finished region after compliance checking.

When a certain ship entity model of a certain ship area is input into an interscan Smart3D for model verification, a model file of the ship entity model is input into the interscan Smart3D, the model file of the ship entity model is analyzed, file attributes, space modeling parameters and attribute values of the model file of the ship entity model are obtained, the model file, the space modeling parameters and the attribute values are correspondingly placed in the space types to which the model file belongs, and further the model file is placed in a subarea space under the attribute space under the corresponding ship area space.

After the modeling space of the part is input by the entity model, the parameters of the modeling space of the part are automatically matched with the modeling number, the attribute value and the like of the input entity model, if the parameters are not matched, correction is needed, corresponding difference information is output, the difference information is displayed to a user through an Intergraph Smart3D, and the user can know which difference values exist in the modeling parameters and the attribute values of the input entity model after knowing the difference values, so that the parameters and the attribute values of the entity model are corrected.

And combining the entity model and the data rule to acquire the required model and check data, thereby completing more complicated data analysis work which cannot be completed by the entity model.

The following is a method for comparing parameters of each layer of the solid model by using the inherent attribute values of each application layer space, and the specific principle is as described above.

As an optional embodiment of the present application, optionally, performing attribute verification on an attribute value of a ship entity model according to the intrinsic attribute value of the space division sub-file and an associated upper file, and generating a required entity model and corresponding verification data, including:

acquiring attribute values of a ship entity model;

comparing the intrinsic attribute value configured on the current space division sub-file with the attribute value of the ship entity model, and judging whether the attribute value of the ship entity model is matched with the intrinsic attribute value configured on the space division sub-file;

if the model quantity information is matched with the model quantity information of the ship entity model, counting and outputting the model quantity information of the ship entity model;

if the model quantity information is not matched with the model quantity information, correcting the attribute value of the ship entity model according to the requirement, and outputting the corrected model quantity information and corresponding checking data of the ship entity model.

As an optional implementation manner of the present application, optionally, after comparing and checking the intrinsic attribute value configured on the current space division subfile with the attribute value of the ship entity model, the method further includes:

comparing the intrinsic attribute value configured on the spatial attribute file of the previous stage of the current spatial division sub-file with the attribute value of the ship entity model, and judging whether the attribute value of the ship entity model is matched with the intrinsic attribute value configured on the spatial attribute file;

if the model quantity information is matched with the model quantity information of the ship entity model, counting and outputting the model quantity information of the ship entity model;

if the model quantity information is not matched with the model quantity information, correcting the attribute value of the ship entity model according to the requirement, and outputting the corrected model quantity information and corresponding checking data of the ship entity model.

As an optional embodiment of the present application, optionally, after comparing and checking the intrinsic attribute value configured on the spatial attribute file with the attribute value of the ship entity model, the method further includes:

comparing the inherent attribute value configured on the space type file of the previous stage of the current space attribute file with the attribute value of the ship entity model, and judging whether the attribute value of the ship entity model is matched with the inherent attribute value configured on the space attribute file;

if the model quantity information is matched with the model quantity information of the ship entity model, counting and outputting the model quantity information of the ship entity model;

if the model quantity information is not matched with the model quantity information, correcting the attribute value of the ship entity model according to the requirement, and outputting the corrected model quantity information and corresponding checking data of the ship entity model.

Therefore, the application compares the inherent attribute and technical requirement with the attribute of the entity model by collecting the entity model data in the space three-dimensional virtual model, and discovers the entity model which does not meet the requirement as soon as possible, and can also count the entity model quantity information of the space region.

It should be noted that, although the above ship modeling application space layer is described by taking several ship regions as an example, those skilled in the art can understand that the present disclosure should not be limited thereto. In fact, the user can flexibly set the ship area according to the actual application scene, so long as the technical function of the application can be realized according to the technical method.

It should be apparent to those skilled in the art that the implementation of all or part of the above-described embodiments of the method may be implemented by a computer program for instructing relevant hardware, and the program may be stored in a computer readable storage medium, and the program may include the steps of the embodiments of the control methods described above when executed. It will be appreciated by those skilled in the art that implementing all or part of the above-described embodiment methods may be implemented by a computer program for instructing relevant hardware, and the program may be stored in a computer readable storage medium, and the program may include the embodiment flow of each control method as described above when executed. The storage medium may be a magnetic disk, an optical disc, a Read-only memory (ROM), a random access memory (RandomAccessMemory, RAM), a flash memory (flash memory), a hard disk (HDD), or a Solid State Drive (SSD); the storage medium may also comprise a combination of memories of the kind described above.

Example 2

Based on the implementation principle of embodiment 1, in another aspect, the present application proposes an apparatus for implementing the modeling method based on the interscan Smart3D, which includes:

the space type definition module is used for defining space types with different characteristics in the three-dimensional modeling environment of the inter Smart3D;

the space attribute definition module is used for defining the space attribute of each type of space;

the space region dividing module is used for dividing the space of each attribute to obtain application spaces under each attribute space;

and the entity model checking module is used for inputting the entity model of the ship into the corresponding application space, checking the attribute of the entity model attribute value, and generating the required entity model and corresponding checking data.

The function and interaction principle of the above modules are specifically described in embodiment 1.

The modules or steps of the application described above may be implemented in a general-purpose computing device, they may be centralized in a single computing device, or distributed across a network of computing devices, or they may alternatively be implemented in program code executable by a computing device, such that they may be stored in a memory device and executed by a computing device, or they may be separately fabricated into individual integrated circuit modules, or multiple modules or steps within them may be fabricated into a single integrated circuit module. Thus, the present application is not limited to any specific combination of hardware and software.

Example 3

Still further, another aspect of the present application further provides an interscan Smart 3D-based modeling method control system, including:

a processor;

a memory for storing processor-executable instructions;

wherein the processor is configured to implement the inter-graph Smart 3D-based modeling method when executing the executable instructions.

Embodiments of the present disclosure control a system that includes a processor and a memory for storing processor-executable instructions. Wherein the processor is configured to implement any of the above-described modeling methods based on the interscan Smart3D when executing the executable instructions.

Here, it should be noted that the number of processors may be one or more. Meanwhile, in the control system of the embodiment of the present disclosure, an input device and an output device may be further included. The processor, the memory, the input device, and the output device may be connected by a bus, or may be connected by other means, which is not specifically limited herein.

The memory is a computer-readable storage medium that can be used to store software programs, computer-executable programs, and various modules, such as: the embodiment of the disclosure relates to a program or a module corresponding to an modeling method based on an interscan Smart 3D. The processor executes various functional applications and data processing of the control system by running software programs or modules stored in the memory.

The input device may be used to receive an input number or signal. Wherein the signal may be a key signal generated in connection with user settings of the device/terminal/server and function control. The output means may comprise a display device such as a display screen.

The foregoing description of the embodiments of the present disclosure has been presented for purposes of illustration and description, and is not intended to be exhaustive or limited to the embodiments disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the various embodiments described. The terminology used herein was chosen in order to best explain the principles of the embodiments, the practical application, or the technical improvement of the technology in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.

Claims (10)

1. The modeling method based on the interscan Smart3D is characterized by comprising the following steps:

defining space types with different characteristics in an interscan Smart3D three-dimensional modeling environment;

defining the space attribute of each type of space;

carrying out space region division on the spaces of all the attributes to obtain application spaces under all the attribute spaces;

inputting the entity model of the ship into a corresponding application space, performing attribute check on the attribute value of the entity model, and generating a required entity model and corresponding check data.

2. The modeling method based on the interscan Smart3D according to claim 1, wherein defining spatial types of different characteristics in a three-dimensional modeling environment of the interscan Smart3D comprises:

defining a plurality of different ship areas according to ship design information;

defining space types corresponding to each ship region in the three-dimensional modeling space of the inter Smart3D according to the defined ship region, and generating a space type file under the space where each ship region is located;

and uploading and storing the space type files corresponding to the ship areas.

3. The modeling method based on interscan Smart3D according to claim 1, wherein defining spatial attributes for each type of space comprises:

acquiring a space type file of each ship area;

setting attribute conditions for the space type files of each ship area according to the attribute of each ship area, and generating space attribute files under each space type file;

uploading and storing space attribute files corresponding to each ship area;

wherein the attribute conditions include: basic attributes and unique attributes;

the basic attribute is set according to the definition number and the definition name;

and setting unique attributes according to the basic attributes of each ship area.

4. The modeling method based on interscan Smart3D according to claim 1, wherein the spatial region division is performed on the spaces of each attribute to obtain application spaces under each attribute space, and the method comprises the steps of:

presetting a region dividing rule;

acquiring a space attribute file of each ship region, dividing the space region of each ship region according to a region division rule, and generating a space division sub-file under each space attribute file;

and transmitting and storing the space division subfiles corresponding to the ship areas.

5. The modeling method based on the interscan Smart3D according to claim 1, wherein inputting the physical model of the ship into the corresponding application space, performing attribute check on the physical model attribute values, and generating the required physical model and the corresponding check data, includes:

inputting a ship entity model to an interscan Smart3D;

analyzing and acquiring basic information of a ship entity model, and placing the ship entity model into a corresponding space division sub-file according to the basic information of the ship entity model;

and carrying out attribute check on the attribute values of the ship entity model according to the space division sub-file and the inherent attribute values of the related upper files, and generating the required entity model and corresponding check data.

6. The modeling method based on interscan Smart3D according to claim 5, wherein performing attribute check on attribute values of a ship entity model according to the intrinsic attribute values of the space division sub-file and the related upper files, and generating a required entity model and corresponding check data, comprises:

acquiring attribute values of a ship entity model;

comparing the intrinsic attribute value configured on the current space division sub-file with the attribute value of the ship entity model, and judging whether the attribute value of the ship entity model is matched with the intrinsic attribute value configured on the space division sub-file;

if the model quantity information is matched with the model quantity information of the ship entity model, counting and outputting the model quantity information of the ship entity model;

if the model quantity information is not matched with the model quantity information, correcting the attribute value of the ship entity model according to the requirement, and outputting the corrected model quantity information and corresponding checking data of the ship entity model.

7. The modeling method based on the interscan Smart3D according to claim 6, further comprising, after comparing and checking the intrinsic attribute values configured on the current space division subfile with the attribute values of the ship entity model:

comparing the intrinsic attribute value configured on the spatial attribute file of the previous stage of the current spatial division sub-file with the attribute value of the ship entity model, and judging whether the attribute value of the ship entity model is matched with the intrinsic attribute value configured on the spatial attribute file;

if the model quantity information is matched with the model quantity information of the ship entity model, counting and outputting the model quantity information of the ship entity model;

if the model quantity information is not matched with the model quantity information, correcting the attribute value of the ship entity model according to the requirement, and outputting the corrected model quantity information and corresponding checking data of the ship entity model.

8. The modeling method according to claim 7, further comprising, after comparing and checking the intrinsic attribute values configured on the spatial attribute file with the attribute values of the ship solid model:

comparing the inherent attribute value configured on the space type file of the previous stage of the current space attribute file with the attribute value of the ship entity model, and judging whether the attribute value of the ship entity model is matched with the inherent attribute value configured on the space attribute file;

if the model quantity information is matched with the model quantity information of the ship entity model, counting and outputting the model quantity information of the ship entity model;

if the model quantity information is not matched with the model quantity information, correcting the attribute value of the ship entity model according to the requirement, and outputting the corrected model quantity information and corresponding checking data of the ship entity model.

9. Apparatus for implementing the modeling method based on interscan Smart3D according to any one of claims 1 to 8, comprising:

the space type definition module is used for defining space types with different characteristics in the three-dimensional modeling environment of the inter Smart3D;

the space attribute definition module is used for defining the space attribute of each type of space;

the space region dividing module is used for dividing the space of each attribute to obtain application spaces under each attribute space;

and the entity model checking module is used for inputting the entity model of the ship into the corresponding application space, checking the attribute of the entity model attribute value, and generating the required entity model and corresponding checking data.

10. A base control system, comprising:

a processor;

a memory for storing processor-executable instructions;

wherein the processor is configured to implement the inter-graph Smart 3D-based modeling method of any of claims 1-8 when executing the executable instructions.