KR20190137464A - Apparatus and method for generating 3d model of power facilities - Google Patents

Abstract

The present invention provides an apparatus and method for generating a power equipment 3D model that enable sharing of 3D models by creating an XML-based power equipment 3D standard model including a power euipqment 3D model, interactions, and a power equipment 3D standard model scheme. The provided apparatus for generating a power equipment 3D model comprises: a power equipment 3D standard model generation module for generating a power equipment 3D standard model; and a power equipment 3D standard model sharing module which manages the power equipment 3D standard model generated by the power equipment 3D standard model generation module and shares the power equipment 3D standard model to an external terminal. The power equipment 3D standard model includes the power equipment 3D model of target power equipment, the interactions which are physical attributes of the target power equipment, and the power equipment 3D standard model scheme.

Description

Apparatus and method for generating 3D model of power equipment {APPARATUS AND METHOD FOR GENERATING 3D MODEL OF POWER FACILITIES}

The present invention relates to an apparatus and method for generating a power plant 3D model, and more particularly, to a power plant 3D model for generating and sharing a 3D model of a power plant in a virtual reality (VR) or augmented reality environment. It relates to a production apparatus and a method.

With the proliferation of virtual reality and augmented reality technologies, development of various devices and contents is required. The device is being developed by a global company, and the content is being developed by various SMEs and venture companies.

In the power sector, various contents for PR, education, and maintenance are being developed using virtual reality and augmented reality technology. In particular, as the effectiveness of training in virtual space for substations, underground power holes, and steel towers, which are areas where workers are constrained by space, is expected, demand for various contents development will increase in the future.

In order to develop VR / AR contents in the power field, 3D modeling of power facilities is required.

However, since the development of virtual environment contents is different depending on the content's goals (ie, education, promotion, maintenance, etc.), developers are developing new 3D models even with the same model. Different.

Accordingly, there is a problem in that the developed 3D model cannot be shared with other contents and the same 3D model is repeatedly generated to waste development period and cost.

To cushion this, existing commercial development engine companies have developed platforms that can trade 3D models (Ex, Unity Store, Unreal Marketplace, etc.) and are provided in the form of Web.

However, since the 3D model used in the power field requires the definition of various physical properties due to the specificity of the power field, it is difficult to utilize a general 3D model made only with an appearance.

Korean Registered Patent No. 10-0874288 (Name: 3D model and asset management system of ships and offshore structures)

The present invention has been proposed to solve the above-described problems, and to generate a 3D standard model of the power facility XML based on the power facility 3D model, interaction and power facility 3D standard model system to share the 3D model. An object of the present invention is to provide an apparatus and method for generating a 3D model of a power equipment.

In order to achieve the above object, the power equipment 3D model generating apparatus according to an embodiment of the present invention includes a power equipment 3D standard model generating module and a power equipment 3D standard model generating module that generate the power equipment 3D standard model. A power equipment 3D standard model sharing module that manages a standard model and shares the power equipment 3D standard model to external terminals, wherein the power equipment 3D standard model includes the power equipment 3D model of the target power equipment and the physical properties of the target power equipment. Interaction and power equipment 3D model standard framework is included.

The utility 3D standard model generation module packages one or more utility standard assets to generate a utility 3D standard model. The utility standard assets generate video, sound, textures, utility 3D models, and utility 3D standard schemes and interactions. It may include. In this case, the power facility 3D standard model generation module may generate a power facility standard asset in an XML file format.

The power equipment 3D model standardization system includes a large classification set as one of power generation, transmission, substation, distribution, and communication based on the application field of the target power equipment, and the power equipment 3D model standardization system is based on the target power equipment. Further comprising, the subclass may be set under the subclass, the subclass may be set under the subclass.

Interactions are set up under a subclass of the utility 3D model standard framework, and the utility 3D standard model generation module sets up interactions that include functionality, attributes, and visualization information, and functions include analog gauges, digital displays, lamps, and meters. It may include real, mobile rotation, and switches, attributes may include information and IoT sensor data, and visualization information may include port and model attributes.

The power facility 3D standard model generation module sets up an interaction based on a GUI, and the interaction is configured in units of nodes, and the power facility 3D model connected to the nodes of the interaction may operate in the virtual environment by the interaction.

The power equipment 3D standard model generation module generates a power equipment 3D standard model with a folder structure, and the folder structure is classified into major classification, medium classification, and small classification, and each folder includes video, sound, texture, and power equipment of the power equipment 3D standard model. Resources of 3D models, utility 3D standards and interactions can be stored.

The power equipment 3D model generation device according to an embodiment of the present invention may further include a power content development support module for supporting an external terminal with a power content development environment using the power equipment 3D standard model managed by the power equipment 3D standard model sharing module. Can be.

In order to achieve the above object, the power equipment 3D model generation method according to an embodiment of the present invention is a power equipment 3D model generation method using the power equipment 3D model generation device, generating a power equipment 3D model corresponding to the target power equipment Setting a power system 3D model standard system of the power equipment 3D model based on the target power equipment, setting up interaction of the power equipment 3D model based on the target power equipment, power equipment 3D model, power equipment 3D Generating a utility standard asset including model standard schemes and interactions; and packaging one or more utility standard assets to generate a utility 3D standard model.

In the step of establishing a 3D model standard system of electric power facilities, the electric power 3D model standard system including large classification, medium classification and small classification set as one of power generation, transmission, substation, distribution and communication is established based on the application field of the target electric power facility. The subclass may be set below the major class, and the subclass may be set below the subclass.

 In the step of setting up the interaction, the interaction is set up under the sub-class of the power equipment 3D model standard system, and the interaction including the function, property, and visualization information of the power equipment 3D model is provided. It may include lamps, materials, movement rotations, and switches, attributes may include information and IoT sensor data, and visualization information may include port and model attributes. In the step of setting up the interaction, the interaction is set based on the GUI, the interaction is configured in units of nodes, and the power equipment 3D model connected to the nodes of the interaction may operate in the virtual environment by the interaction.

In the generating of the utility standard asset, the utility standard asset further including a moving picture, sound, and texture may be generated, but the utility standard asset in the XML file format may be generated.

In the step of generating a power equipment 3D standard model, a power equipment 3D standard model having a folder structure is generated, and the folder structure is classified into a large classification, a medium classification, and a small classification, and each folder includes a video, sound, texture, Resources of utility 3D models, utility 3D standards and interactions can be stored.

According to the present invention, an apparatus and method for generating a power equipment 3D model generates a power equipment standard asset including a power equipment 3D model, an interaction, and a power equipment 3D standard model system, and packages the power equipment 3D standard model to generate a power equipment 3D standard model. It is possible to define various physical properties due to the specificity of the power field, so that the manufactured 3D model can be used in the power field and general field.

In addition, the power equipment 3D model generating apparatus and method generates an electric power 3D standard model based on XML, so that the 3D model can be easily shared with other contents, thereby preventing duplicate generation of the same 3D model, and thus, development period and cost. There is an effect that can be minimized.

In addition, the power equipment 3D model generation device and method has the effect that can utilize the existing 3D model authoring technology (3D Max, Maya, etc.) as it is in the production of power equipment 3D model, rather than the use of a separate production technology (tool).

In addition, the power equipment 3D model generation device and method does not define properties / functions separately in the power equipment 3D model, but generates the power equipment 3D standard model by adding the properties / functions to the power equipment 3D model based on the existing virtual reality development engine. There is an effect that the content developer can modify to the desired form.

In addition, the power equipment 3D model generation device and method provides a plug-in form without creating a virtual reality development engine utilizing the power equipment 3D standard model, it is effective to utilize the existing virtual reality development engine.

In addition, the power equipment 3D model generation device and method is to share the power equipment 3D standard model on the web to utilize a variety of content, it is possible to develop content in a short period of time with minimal modification of the power equipment 3D model in virtual reality content development have.

In addition, the 3D model generation device and method of the power facility can develop various contents through the 3D standard model of the power facility, thereby providing various services to the power industry workers and power consumers by producing various VR contents such as education, training, and operation in the electric power field. Since this is possible, there is an effect that can contribute to the improvement of overall satisfaction and service of the power industry.

1 is a view for explaining a power equipment 3D model generation device according to an embodiment of the present invention.
2 to 17 is a view for explaining the power equipment 3D standard model generation module of FIG.
18 is a view for explaining the power equipment 3D standard model sharing module of FIG.
19 and 20 are diagrams for describing the power content development support module of FIG. 1.
21 is a flowchart illustrating a power facility 3D model generation method according to an embodiment of the present invention.

Hereinafter, the most preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily implement the technical idea of the present invention. . First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

Hereinafter, the power equipment 3D model generation device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 1 is a view for explaining a power equipment 3D model generation device according to an embodiment of the present invention. 2 to 17 are diagrams for describing the power equipment 3D standard model generation module of FIG. 1, FIG. 18 is a diagram for explaining the power equipment 3D standard model sharing module of FIG. 1, and FIGS. 19 and 20 are FIGS. 1 is a diagram for describing a power content development support module 1.

Referring to FIG. 1, the power equipment 3D model generation apparatus according to an embodiment of the present invention includes a power equipment 3D standard model generation module 100, a power equipment 3D standard model sharing module 200, and a power content development support module 300. It includes.

Here, the power facility 3D standard model generation module 100, the power facility 3D standard model sharing module 200, and the power content development support module 300 are illustrated as being configured as one device, but are not limited thereto. It can be configured as a separate device or server.

The power facility 3D standard model generation module 100 generates a power facility 3D standard model 500 corresponding to the target power facility. The power facility 3D standard model generation module 100 generates the power facility 3D standard model 500, which is a 3D model that packages the power facility standard assets 400 of the target power facility. Here, the packaging is a video system 410, sound 420, texture 430, power equipment 3D model 440, interaction 450, power equipment 3D model standard system that constitutes the power equipment standard asset 400 (460) means an integrated process. The power facility standard asset 400 refers to a form in which attributes, functions, and visualization information are given to a 3D model manufactured by a commercial tool, and the power facility standard asset 400 corresponds to one power facility. The utility 3D standard model 500 may be comprised of one or more utility standard assets 400.

Referring to FIG. 2, the power equipment 3D standard model generation module 100 includes a video 410, a sound 420, a texture 430, a power equipment 3D model 440, an interaction 450, and the like related to the target power equipment. Create a utility standard asset 400 that includes a utility 3D model standard framework 460. The power facility standard asset 400 includes an XML file defining a power facility 3D model, an image, a sound 420, a 3D model definition format of a virtual reality development engine, and a power facility 3D standard model 500. The utility standard asset 400 is generated through packaging and is configured to be shared and reused. The power facility standard asset 400 can be set to nine kinds of movements, rotations, switches, lamps, and ports (power flows), and the interaction of the power facility 3D model 440 can be given in virtual reality. It is configured to be.

The power facility 3D standard model generation module 100 generates a power facility 3D model 440 corresponding to the target power facility. The power equipment 3D standard model generation module 100 generates a power equipment 3D model 440 corresponding to the target power equipment by using a commercial tool. Here, the power equipment 3D model 440 is manufactured through a commercial tool such as 3D Max, Maya, etc., and is an example of a 3D model having a file format such as FBX, 3DS, OBJ, or the like.

The power equipment 3D standard model generation module 100 sets the power equipment 3D model standard system 460 of the power equipment 3D model 440 based on the target power equipment. Here, the power facility 3D model standard system 460 is to secure the diversity, unity, uniformity, and reusability of the power facility 3D model 440 that is used for various contents for power virtual reality-based education, training, and operation. It is a set system. The power facility 3D model standard system 460 is a system defined to support the creation of attributes (information), functions (animation), etc. in the power facility 3D model 440 utilized for virtual reality-based contents in the power field. . The power facility 3D model standard system 460 is defined in an XML file format capable of storing information and functions of the power facility 3D model 440 and the power facility 3D model 440 to be utilized in a virtual reality development engine.

The power facility 3D model standard system 460 is a system that analyzes power facilities of the power system and classifies them into specific criteria. The power equipment 3D model standard system 460 defines power equipments classified into major classification, medium classification, and small classification. Referring to Figures 3 to 8, the large category is divided into the power generation, power transmission, substation, distribution, communication fields, the middle classification and small classification is set under the large classification according to the characteristics of the power facilities.

The power equipment 3D standard model generation module 100 sets up the power equipment 3D model standard system 460 in XML format to enable reuse of the packaged power equipment standard asset 400 and the power equipment 3D standard model 500. do.

The power facility 3D standard model generation module 100 sets up a physical interaction 450 of the power facility 3D model 440 based on the target power facility. The interaction 450 refers to physical properties of the power facility 3D model 440 in the virtual environment.

Referring to FIG. 9, the interaction 450 is set below the power facility 3D model standard framework 460. Interaction 450 includes power facility information, including functionality, attributes, and visualization information. The interaction 450 includes concrete information set under each power facility information (ie, function, attribute, visualization information). Functions include analog gauges, digital displays, lamps, materials, moving rotations and switches, attributes include information and IoT sensor data, and visualization information includes port and model attributes.

The utility 3D standard model generation module 100 may provide an interaction editor for setting the interaction 450 of the utility standard asset 400. At this time, the type of interaction 450 that can be set through the interaction editor is shown in FIG. 10.

The interaction editor configures the interaction 450 on a node-by-node basis, and the nodes have their own characteristic functions. The interaction editor operates in connection with the power facility 3D model 440, and the function of the power facility is set according to the connection of the nodes.

The interaction editor includes a node editor window for defining nodes. The node editor window is composed of a unique node-based editor window in the virtual reality development engine, and can be added as an add-on function of the existing virtual reality development engine. Through this, the power facility 3D standard model generation module 100 sets the interaction 450 of the 3D model intuitively through the GUI-based interaction editor, unlike the conventional method of defining the properties of the 3D model based on text such as a scripting language. Can be.

Referring to FIG. 11, the node editor window defines the power facility 3D model 440 as a reference node, and generates interaction 450 information to be defined in each node. The node editor window sets the attribute value by connecting the interaction 450 nodes with a line (edge) based on the power facility 3D model 440 node. For example, referring to FIGS. 12 and 13, an analog gauge node is a node that can express information (power value) transmitted to a port to an analog gauge attached to a power facility. That is, it can be set and modified in the GUI screen.

The utility 3D standard model generation module 100 generates the utility standard asset 400 in XML format. For example, referring to FIG. 14, the power facility 3D standard model generation module 100 may write information related to the power facility 3D model 440, the power facility 3D model standard framework 460, and the interaction 450 in an XML format. Create a utility standard asset 400.

15 to 17, the power equipment 3D standard model generation module 100 may package (package) one or more power equipment standard assets 400 to generate the power equipment 3D standard model 500. The power equipment 3D standard model generation module 100 classifies (categories) the power equipment standard asset 400 based on the power equipment 3D standard system to generate the power equipment 3D standard model 500 having a folder structure. At this time, the folder structure is configured in accordance with the classification (category) definition of the power equipment 3D model standard system 460. The folder structure is classified into large category, medium category, and small category, and stores various resources (data or information) in each folder. The resources that make up the power facility 3D standard model 500 are 3D model, MP4 (video 410), Prefab (interaction 450 motion function), sound (.mp4), texture 430, XML (power facility 3D Each of which is stored in a folder such as model standard framework 460). The power facility 3D standard model generation module 100 proceeds with the package in the state in which the resource structure composed of a folder structure is prepared as the power facility 3D standard model 500 and integrates one into a file.

The power equipment 3D standard model sharing module 200 manages the power equipment 3D standard model 500. The power facility 3D standard model sharing module 200 integrates and manages resources such as 3D models, VR models, and power facility standard assets 400 to support virtual reality content creation in the power field, and provides content management to users. Perform the function.

The power facility 3D standard model sharing module 200 shares the power facility 3D standard model 500 on a web basis. The power equipment 3D standard model sharing module 200 shares the power equipment 3D standard model 500 generated by the power equipment 3D standard model generation module 100 to other developers on a web basis.

The power facility 3D standard model sharing module 200 provides a user authentication, a user convenience function, an administrator convenience function, etc. to share the power facility 3D standard model 500 on a web basis (see FIG. 18).

The power equipment 3D standard model sharing module 200 mainly manages the power equipment 3D standard model 500 and the power equipment 3D model standard system 460, and access rights (read / write / delete, etc.) of data according to the user's authority. To limit.

The power facility 3D standard model sharing module 200 builds a virtual reality content resource management, upload and download technology base environment. The power facility 3D standard model sharing module 200 sets access rights for each user based on encryption and security schemes for various users. The power equipment 3D standard model sharing module 200 provides the power equipment 3D standard model 500, the power equipment standard asset 400, and the like based on the base environment and the access control authority for each account.

The power equipment 3D standard model sharing module 200 configures a home screen that provides the power equipment 3D standard model 500, and a category through which the user can intuitively search for the power equipment 3D standard model 500. It provides a page where you can check the search bar and detailed properties.

The power content development support module 300 provides a developer with an environment in which to develop power content using the power facility 3D standard model 500. The developer downloads the power facility 3D standard model 500 through the power content development support module 300 and then modifies or reuses the power facility to develop power content.

The power content development support module 300 utilizes the power facility 3D standard model 500 generated based on the power facility 3D standard system, so that content creators can conveniently and quickly create power content virtual reality content in the power facility 3D standard. The model 500 is disposed in a virtual space and supports a production environment including node connection and model management. That is, the power content development support module 300 supports the generation of power virtual reality content using the power facility 3D standard model 500 of the power facility 3D standard system. The power content development support module 300 arranges the power facility 3D standard model 500 in a virtual space, and creates an environment in which power virtual reality content can be quickly and easily developed through node connection and power facility standard asset 400 management. Support.

The power content development support module 300 provides an integrated development environment for power facilities to conveniently manage content specific to the power facilities, and connects input / output ports between power facilities through the power facility 3D standard model 500. It provides the function to send and receive data between power facilities by providing the function.

Referring to FIGS. 19 and 20, the power content development support module 300 may determine electrical characteristics (capacity, number of input and output, etc.) of the power facility 3D standard model 500 based on the power facility 3D model standard system 460. It can be connected to the edge between nodes. The power content development support module 300 may implement power flow in a virtual space through a node-to-node connection.

Hereinafter, a power facility 3D model generation method according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 21 is a flowchart illustrating a method for generating a power facility 3D model according to an embodiment of the present invention.

The power equipment 3D model generating apparatus generates a power equipment 3D model 440 corresponding to the target power equipment (S100). The power equipment 3D model generating apparatus generates a power equipment 3D model 440 corresponding to the target power equipment by using a commercial tool. Here, the power equipment 3D model 440 is manufactured through a commercial tool such as 3D Max, Maya, etc., and is an example of a 3D model having a file format such as FBX, 3DS, OBJ, or the like.

The power equipment 3D model generating apparatus sets the power equipment 3D model standard system 460 of the power equipment 3D model 440 based on the target power equipment (S200). Here, the power facility 3D model standard system 460 is to secure the diversity, unity, uniformity, and reusability of the power facility 3D model 440 that is used for various contents for power virtual reality-based education, training, and operation. It is a set system. The power facility 3D model standard system 460 is a system defined to support the creation of attributes (information), functions (animation), etc. in the power facility 3D model 440 utilized for virtual reality-based contents in the power field. . The power facility 3D model standard system 460 is defined in an XML file format capable of storing information and functions of the power facility 3D model 440 and the power facility 3D model 440 to be utilized in a virtual reality development engine.

The power facility 3D model standard system 460 is a system that analyzes power facilities of the power system and classifies them into specific criteria. Power facility 3D model generator defines power equipment into major, middle, and small categories. At this time, the large classification is classified into the power generation, transmission, substation, distribution, and communication fields, the middle classification and the small classification is set under the large classification according to the characteristics of the power equipment.

The power equipment 3D model generating apparatus sets the interaction 450 of the power equipment 3D model 440 based on the target power equipment (S300). The power equipment 3D model generation device sets up an interaction 450 of the power equipment 3D model 440 through a GUI-based editor. The interaction 450 refers to physical properties of the power facility 3D model 440 in the virtual environment. The interaction 450 is set under the power facility 3D model standard framework 460. In the power equipment 3D model generating apparatus, the interaction 450 includes power equipment information including function, attribute, and visualization information. The power plant 3D model generation device sets up an interaction 450 that includes functions including analog gauges, digital displays, lamps, materials, moving rotations, and switches. The power equipment 3D model generation device sets up an interaction 450 including attributes including information and IoT sensor data. The power equipment 3D model generating apparatus sets up an interaction 450 including visualization information including port and model attributes.

The power equipment 3D model generating apparatus generates a power equipment standard asset 400 including the power equipment 3D model 440, the power equipment 3D model standard system 460, and the interaction 450 (S400). The power equipment 3D model generating device includes a power equipment standard including a video 410, a sound 420, a texture 430, a power equipment 3D model 440, a power equipment 3D model standard system 460, and an interaction 450. Generate asset 400 in XML format.

The power equipment 3D model generation device packages one or more power equipment standard assets 400 to generate the power equipment 3D standard model 500 (S500). The power equipment 3D model generating apparatus classifies (categories) the power equipment standard asset 400 based on the power equipment 3D standard system to generate the power equipment 3D standard model 500 having a folder structure. At this time, the folder structure is configured in accordance with the classification (category) definition of the power equipment 3D model standard system 460. The folder structure is classified into large category, medium category, and small category, and stores various resources (data or information) in each folder. The resources that make up the power facility 3D standard model 500 are 3D model, MP4 (video 410), Prefab (interaction 450 motion function), sound (.mp4), texture 430, XML (power facility 3D Each of which is stored in a folder such as model standard framework 460). The power equipment 3D model generating device proceeds with a package prepared with the power structure 3D standard model 500 configured as a folder structure and integrates one into a file.

As described above, the apparatus and method for generating a power equipment 3D model generates a power equipment standard asset including a power equipment 3D model, an interaction, and a power equipment 3D standard model system, and packages the power equipment 3D standard model to generate a power equipment 3D standard model. It is possible to define various physical properties due to the specificity of the power field, so that the manufactured 3D model can be used in the power field and general field.

In addition, the power equipment 3D model generation device and method generates the power equipment 3D standard model based on XML, so that the 3D model can be easily shared with other contents, thereby preventing duplicate generation of the same 3D model, and thus, development period and cost. There is an effect that can be minimized.

In addition, the power equipment 3D model generation device and method has the effect that can utilize the existing 3D model authoring technology (3D Max, Maya, etc.) as it is in the production of power equipment 3D model, rather than the use of a separate production technology (tool).

In addition, the power equipment 3D model generation device and method does not define properties / functions separately in the power equipment 3D model, but generates the power equipment 3D standard model by adding the properties / functions to the power equipment 3D model based on the existing virtual reality development engine. There is an effect that the content developer can modify to the desired form.

In addition, the power equipment 3D model generation device and method provides a plug-in form without creating a virtual reality development engine utilizing the power equipment 3D standard model, it is effective to utilize the existing virtual reality development engine.

In addition, the power equipment 3D model generation device and method is to share the power equipment 3D standard model on the web to utilize a variety of content, it is possible to develop content in a short period of time with minimal modification of the power equipment 3D model in virtual reality content development have.

In addition, the 3D model generation device and method of the power facility can develop various contents through the 3D standard model of the power facility, thereby providing various services to the power industry workers and power consumers by producing various VR contents such as education, training, and operation in the electric power field. Since this is possible, there is an effect that can contribute to the improvement of overall satisfaction and service of the power industry.

Although a preferred embodiment according to the present invention has been described above, modifications can be made in various forms, and those skilled in the art will appreciate various modifications and modifications without departing from the claims of the present invention. It is understood that it may be practiced.

100: power equipment 3D standard model generation module
200: power equipment 3D standard model sharing module
300: power content development support module
400: Power Plant Standard Asset 410: Video
420: Sound 430: Texture
440: power equipment 3D model 450: interaction
460: Power Equipment 3D Model Standard System 500: Power Equipment 3D Standard Model

Claims (20)

A power equipment 3D standard model generation module for generating a power equipment 3D standard model; And
A power equipment 3D standard model sharing module for managing the power equipment 3D standard model generated by the power equipment 3D standard model generation module and sharing the power equipment 3D standard model to an external terminal,
The power equipment 3D standard model includes a power equipment 3D model of a target power equipment, an interaction system that is a physical property of the target power equipment, and a power equipment 3D model generation system. The method of claim 1,
The power equipment 3D standard model generation module packages one or more power equipment standard assets to generate a power equipment 3D standard model,
The power equipment standard asset includes a video equipment, sound, texture, power equipment 3D model, power equipment 3D standard framework and interaction. The method of claim 2,
The power equipment 3D standard model generation module generates a power equipment 3D model generation device for generating the power equipment standard assets in the XML file format. The method of claim 1,
The power equipment 3D model standard system is a power equipment 3D model generation device comprising a large classification set to one of power generation, transmission, substation, distribution and communication based on the application field of the target power equipment. The method of claim 4, wherein
The power equipment 3D model standard system further includes a medium classification and a small classification set based on the target power equipment, wherein the middle classification is set below the large classification, and the small classification is a power equipment 3D model generating device set below the middle classification. . The method of claim 5,
And wherein the interaction is set below a sub-category of the power facility 3D model standard system. The method of claim 1,
The power equipment 3D standard model generation module sets up an interaction including function, property, and visualization information,
The function includes an analog gauge, a digital display, a lamp, a material, a mobile rotation and a switch, the attribute includes information and IoT sensor data, and the visualization information includes a port and model attribute. Generating device. The method of claim 1,
The power equipment 3D standard model generation module sets the interaction based on a GUI, and the interaction is configured in units of nodes, and the power equipment 3D model connected to the node of the interaction is a power equipment 3D operating in a virtual environment by the interaction. Model generation device. The method of claim 1,
The power equipment 3D standard model generation module generates a power equipment 3D standard model having a folder structure.
The folder structure is classified into large category, medium category, and small category, and each folder is a power equipment 3D model generating apparatus in which video, sound, texture, power equipment 3D model, power equipment 3D standard system and interaction resources of power equipment 3D standard model are stored. . The method of claim 1,
And a power content development support module for supporting an external terminal with a power content development environment using the power facility 3D standard model managed by the power facility 3D standard model sharing module. In the power facility 3D model generation method using a power facility 3D model generation device,
Generating a power facility 3D model corresponding to the target power facility;
Setting a power facility 3D model standard system of the power facility 3D model based on the target power facility;
Setting up an interaction of a power facility 3D model based on the target power facility;
Generating a power facility standard asset including the power facility 3D model, the power facility 3D model standard framework and the interaction; And
Packaging one or more power utility standard assets to generate a power facility 3D standard model. The method of claim 11,
In the step of setting the power equipment 3D model standard system, the power equipment that sets the power equipment 3D model standard system including a large classification set to one of power generation, transmission, substation, distribution and communication based on the application field of the target power equipment. How to create a 3D model. The method of claim 12,
In the step of setting the power equipment 3D model standard system, the power equipment 3D model standard system further includes a medium classification and a small classification based on the target power facility, and the middle classification is set below the major classification. Small classification is a power facility 3D model generation method set below the middle classification. The method of claim 13,
And in the step of establishing the interaction, setting up the interaction under the sub-classification of the power facility 3D model standard system. The method of claim 11,
In the setting of the interaction, the power facility 3D model generation method of setting up an interaction including the function, property, and visualization information of the power facility 3D model. The method of claim 15,
The function includes an analog gauge, a digital display, a lamp, a material, a mobile rotation and a switch, the attribute includes information and IoT sensor data, and the visualization information includes a port and model attribute. How to produce. The method of claim 11,
In the setting of the interaction, the interaction is set based on the GUI, and the interaction is configured in units of nodes, and the power equipment 3D model connected to the nodes of the interaction is a power equipment 3D model operating in a virtual environment by the interaction. How to produce. The method of claim 11,
Generating the power facility standard asset further comprising a moving picture, sound, and texture. The method of claim 11,
Generating the power facility standard asset in the XML file format. The method of claim 11,
In the generating of the power facility 3D standard model, a power facility 3D standard model having a folder structure is generated.
The folder structure is classified into a major classification, a middle classification, and a small classification, and each folder generates a power facility 3D model in which video, sound, texture, power facility 3D model, power facility 3D standard system, and interaction resources of the power facility 3D standard model are stored. .

Images