TWM618628U - The apparatus of engineering automation design and management - Google Patents

Abstract

The present invention provides the apparatus including a manage platform and a standardization form. The manage platform further including a modeling unit, a graphic unit, a storage unit, and a check unit. The user of the manage platform could registered and make plenty of different project, and assign the member. When a data is filled in the standardization form, it could upload and import to the manage platform, and be transferred to a stereograph via the modeling unit.

Description

Engineering automation design management device

This authoring department is about an engineering automation design management device, especially the conversion of parameter information into a solid model diagram through standardized forms, and the progress of different engineering projects on the management platform.

Traditional 2D engineering drawing formats are easy to miss. Traditional 2D is often due to insufficient horizontal coordination, which increases the amount of on-site construction modification drawings. In the increasingly complex architectural design, traditional 2D drawings cannot simulate 3D images, and traditional 2D cannot be synchronized in three views. Modifying the engineering drawing, so that it can link and automatically update the drawing, the collaborative work between the structure and the equipment and the building is one of the issues that needs to be solved or improved.

The actuarial nature of traditional 2D engineering drawings is low, and there is no complete storage database. In the construction plan, the on-site feeding and construction procedures such as tower cranes cannot accurately correspond to the completion of the project construction process and sequence, and it is easy to cause delays and reduce project benefits. , And the maintenance and management of its model database is also quite difficult.

In the past, during the 2D drawing operation, the plan had to set the upstream and downstream delivery time of each professional and the related drawing frozen version to ensure the consistency of the drawing version. This often resulted in a long design time and the completion of the civil version revision. Later, the water ring can produce or confirm related illustrations, which leads to a long design period and difficult quality control.

Therefore, after observing the above-mentioned deficiencies, the creator of this case came into being.

In order to achieve the above purpose, the purpose of this creation is to provide an engineering automation design management device.

It mainly includes a management platform and standardized forms. The management platform further includes a modeling unit, a drawing unit, a storage unit, and a verification unit.

Preferably, the management platform can be used by users or operators after connecting and logging in, and different projects can be created on the management platform, and the person in charge or supervisor of the project can be set, and the person in charge or supervisor can modify or View the data or graphics in the project.

When the corresponding data is filled in the standardized form, these data form the so-called parameter information, that is, what information needs to be filled in the standardized form is not a simple list, but is specially designed to make the standardized form available Quickly convert into stereo model diagrams.

Preferably, the modeling unit of the management platform reads or uploads or imports the standardized form through personnel, so that the modeling unit converts the parameter information in the standardized form into a solid model diagram.

Preferably, the drawing unit is more precisely an auxiliary unit in the modeling unit, and mainly outputs the three-dimensional model drawing generated by the modeling unit as a plan view or drawing information.

Preferably, the storage unit is a database of the management platform, which stores all project standardized forms, three-dimensional model diagrams, plan diagrams, graphic information, etc. data and data, and the management platform is used for users or operators Browse query or reference. If there is a project of the same type in the future, the project data in the database can be copied to a new project. You can also analyze the historical data to further understand the status of each project, and how to adjust and improve the construction in the future. quality.

Preferably, the checking unit mainly checks the required parameter information entered in the standardized form, and the checking unit performs a stability check based on the parameter information to confirm stability.

The engineering automation design management method can shorten the time cost of analysis design and manpower drawing.

The device of this creation can be implemented in the following ways.

Set up a standardized form, which is uploaded or imported to the management platform through the responsible personnel. The standardized form contains multiple parameter information, which corresponds to different design components.

Convert the standardized form of the first step into a three-dimensional diagram through a modeling program.

Among them, the modeling program captures the parameter information in the standardized form, and creates the three-dimensional model diagram according to the corresponding design element according to the parameter information. Therefore, through the transformation of the modeling program, the data can be converted into a three-dimensional diagram.

Convert the generated three-dimensional view into a plan view.

Among them, it is also through the modeling program to convert the three-dimensional diagram into the plane diagram that is more commonly used in engineering construction.

After the standardized form is set up, the person in charge or the pipeline engineering manufacturer fills in the corresponding data in sequence according to the specific specification list provided in the form, which is the parameter information required for subsequent modeling, and the standardized form will be integrated Import or upload to the management platform, and perform a stability check on all data. The stability check system is used to confirm stability.

Preferably, each standardized form represents a professional item, such as: plumbing route, electrical configuration, floor, etc. After the modeling program transforms the parameter information in the standardized form into a solid model diagram, each standardized The three-dimensional model diagrams generated by the form will be superimposed together. At this time, you can check whether there are conflicts between the three-dimensional model diagrams of different pipelines in the management platform.

If you find conflicts between the three-dimensional model diagrams of various disciplines (such as pipelines), you can directly modify them on the management platform, directly modify the data in the standardized form corresponding to the professional project, and you can again Quickly generate a new three-dimensional model diagram through the modeling program to confirm whether the modification is completed or conforms.

In order to let those who are familiar with the art understand the purpose, features and effects of this creation, the following specific embodiments are used in conjunction with the accompanying drawings to explain this creation in detail as follows.

The present creative concept will now be explained more fully hereinafter with reference to the accompanying drawings in which an exemplary embodiment of the present creative concept is shown. Hereinafter, the advantages and features of the creative concept and the method of achieving it will be apparent by the exemplary embodiments described in more detail with reference to the accompanying drawings. However, it should be noted that the present creative concept is not limited to the following exemplary embodiments, but can be implemented in various forms. Therefore, the exemplary embodiments are provided only to expose the creative concept and enable those familiar with the art to understand the category of the creative concept. In the drawings, the exemplary embodiments of the creative concept are not limited to the specific examples provided herein and are exaggerated for clarity.

The terms used herein are only used to illustrate specific embodiments, and are not intended to limit the creation. Unless the context clearly indicates otherwise, the terms "a" and "the" in the singular form used herein are intended to also include the plural form. The term "and/or" as used herein includes any and all combinations of one or more of the related listed items. It should be understood that when an element is referred to as being “connected” or “coupled” to another element, the element may be directly connected or coupled to the other element or intervening elements may be present.

Similarly, it should be understood that when an element (such as a layer, region, or substrate) is referred to as being "on" another element, the element can be directly on the other element, or intervening elements may be present. In contrast, the term "directly" means that there are no intermediate components. It should be understood that when the terms "include" and "include" are used in this text, it means that the stated features, integers, steps, operations, elements, and/or components exist, but do not exclude one or more other features , Integers, steps, operations, elements, components, and/or the existence or addition of groups thereof.

In addition, the exemplary embodiment in the detailed description will be explained with a cross-sectional view as an idealized exemplary diagram of the present creative concept. Accordingly, the shape of the exemplary figure can be modified according to manufacturing technology and/or allowable errors. Therefore, the exemplary embodiments of the creative concept are not limited to the specific shapes shown in the exemplary figures, but may include other shapes that can be produced according to the manufacturing process. The regions illustrated in the drawings have general characteristics and are used to illustrate the specific shape of the element. Therefore, this should not be regarded as limited to the scope of this creative concept.

It should also be understood that although the terms "first", "second", "third", etc. may be used in this specification to describe various elements, these elements should not be limited to these terms. These terms are only used to distinguish each element. Therefore, the first element in some embodiments may be referred to as the second element in other embodiments, and this does not deviate from the teaching content of this creation. The exemplary embodiments of the aspect of the creative concept illustrated and described herein include their complementary counterparts. Throughout this specification, the same reference number or the same indicator represents the same element.

In addition, the exemplary embodiments are described herein with reference to cross-sectional views and/or plan views, where the cross-sectional views and/or plan views are idealized exemplary explanatory diagrams. Therefore, it is expected that there will be a deviation from the illustrated shape due to, for example, manufacturing technology and/or tolerances. Therefore, the exemplary embodiments should not be viewed as being limited to the shapes of the regions shown herein, but are intended to include shape deviations caused by, for example, manufacturing. Therefore, the regions shown in the figures are schematic, and their shapes are not intended to illustrate the actual shape of the regions of the device, nor to limit the scope of the exemplary embodiments.

Figure 1 is a schematic diagram of the engineering automation design management device created according to this invention. As shown in Figure 1, the present authoring engineering automation design management device mainly includes a management platform 10 and a standardized form 20. The management platform 10 further includes a modeling unit 11, a drawing unit 12, a storage unit 13, and a verification unit 14. .

Specifically, the management platform 10 can be used by users or operators after logging in, and different projects can be created on the management platform 10, and the person in charge or supervisor of the project can be set, and the person in charge or supervisor can modify Or view the data or graphics in the project.

Specifically, the standardized form 20 is shown in FIG. 2. The specific specification list D1 contained in the standardized form 20 is specially designed. When the corresponding data D2 is filled in the standardized form 20, these data D2 forms the so-called parameter information, that is, what data needs to be filled in the standardized form 20 is not a simple list, but is specially designed so that the standardized form 20 can be quickly converted into a solid model diagram.

Specifically, the modeling unit 11 of the management platform 10 reads or uploads or imports the standardized form 20 through personnel, so that the modeling unit 11 converts the parameter information in the standardized form 20 into a solid model diagram, which can also be said It is fast and direct to convert text or numbers or labels into graphics.

Specifically, the drawing unit 12 is more precisely an auxiliary unit in the modeling unit 11, and mainly outputs the three-dimensional model diagram generated by the modeling unit 11 as a plan view or drawing information, where the drawing information may include calculations. The category, unit, specification, quantity, and/or amount of engineering components included in the three-dimensional model diagram are shown.

Specifically, the storage unit 13 is a database of the management platform 10, which stores all project standardized forms 20, three-dimensional model diagrams, plan diagrams, graphic information, and other data and data. The management platform provides users with or The operator can browse and query or refer to, if there is a project of the same type in the future, the engineering data in the database can be copied to a new project, and the historical data in the database of the storage unit 13 can be analyzed to understand the history through the management platform 10 Data analysis can further understand the status of each project and how to make subsequent adjustments to improve the quality of construction.

Specifically, the checking unit 14 mainly checks the required parameter information entered in the standardized form 20, and the checking unit 14 performs a stability check based on the parameter information to confirm stability.

Specifically, after the modeling unit 11 transforms the multiple standardized forms 20 into solid model diagrams and superimposes them, the checking unit 14 can further perform conflict checking on the superimposed solid model diagrams. Only after confirming that there are no conflicts will the three-dimensional model diagrams be checked. The model diagram is used for subsequent operations and utilization.

The application examples of this creation are described as follows:

Specifically, a standardized form is set up, the standardized form is uploaded or imported to the management platform through a responsible person, and the standardized form includes a plurality of parameter information corresponding to different design elements.

Among them, the standardized form can refer to Figure 2. Figure 2 is an example of creating a standardized form. It is not used to limit the content or form of the form. However, the standardized form in Figure 2 must at least contain specific The specification list D1, and the corresponding data D2, this standardized form is the most basic and also the most important part in this authoring method.

Specifically, an over-modeling program converts the standardized form into a three-dimensional diagram.

Among them, the modeling program grabs the parameter information in the standardized form, and creates the three-dimensional model diagram according to the corresponding design components according to the parameter information. The parameter information contained in the standardized form is shown in Figure 2 For data D2, each data D2 corresponds to a design element. Therefore, through the conversion of the modeling program, the data D2 can be converted into a three-dimensional diagram.

Specifically, the generated three-dimensional view is further converted into a plan view.

Among them, it is also through the modeling program to convert the three-dimensional diagram into the plane diagram that is more commonly used in engineering construction.

It should be further explained that it further includes an input step and a check step.

Specifically, after the standardized form is established, the person in charge or the pipeline engineering manufacturer fills in the corresponding data D2 in sequence according to the specific specification list D1 provided in the form, which is the parameter information required for subsequent modeling, and at the same time The standardized form will be imported or uploaded to the management platform, and the stability check of all data D2 will be carried out. The stability check system is used to confirm the stability.

It needs to be further explained that each standardized form represents a professional item, such as: plumbing route, electrical configuration, floor, etc. After the modeling program transforms the parameter information in the standardized form into a solid model diagram, each The three-dimensional model diagrams generated by the standardized form will be superimposed together. At this time, you can check whether there are conflicts between the three-dimensional model diagrams of different pipelines in the management platform.

Specifically, if conflicts between the three-dimensional model diagrams of various disciplines (such as pipelines) are found, they can be corrected directly on the management platform, and the data D2 in the standardized form corresponding to the professional project can be directly modified. And it can quickly generate a new three-dimensional model diagram through the modeling program again and confirm whether the modification is completed or conforms to it.

Specifically, if the conflict check finds that there is no conflict or there is no conflict between the modified pipelines, the superimposed complete three-dimensional model can be further calculated through the management platform for subsequent calculation of the engineering construction data and stored in the database of the management platform.

In addition, for the convenience of description, the following examples of the creation of the present invention, but it should be noted that it is not limited to the creation of the management platform or the style or display mode of the modeling program.

First of all, please refer to Figure 3 and Figure 4. Figure 3 shows a schematic diagram of the modeling program created according to the present invention.

Specifically, open the modeling program on the management platform and choose to read the data. In this area, select the standardized form that has entered the parameter information, and upload or import the standardized form into the modeling program. Note here Yes, the x, y, and z coordinate translations below are not technical features of this creation, so I won’t describe them in detail here, but the translations will affect the stereograms generated by subsequent modeling. The translations can be obtained through previous calculations. Know.

After uploading or importing the standardized form, you can select the model creation tab, and the modeling program will convert the data D2 into a solid model diagram according to the parameter information in the standardized form.

It is important to note that a project is usually composed of multiple professional projects, so there will be multiple standardized forms that need to be converted. You can upload or import repeatedly to read the data, and then build the model. Multiple three-dimensional model diagrams can be superimposed on the modeling program of the management platform, as shown in Figure 4.

Among them, Figure 4 is the result of superimposing multiple three-dimensional model diagrams, and related information is also displayed in the modeling program, so that the operator can clearly know which professional items are superimposed in the three-dimensional model diagram.

It should be further explained that please refer to Figure 3, Figure 5, Figure 6 and Figure 7 successively to illustrate related application examples after the creation of the three-dimensional model diagram.

Specifically, it can be seen from Fig. 3 that the tab for exporting image assets is also included, where the function of exporting image assets can be subdivided into 2D plan view output, auxiliary quantity calculation, and historical data analysis.

Specifically, the 2D plan output is mainly to convert the superimposed complete three-dimensional model into a plan through a modeling program. As shown in Figure 5, the plan is still used in most construction sites. Therefore, in the creation method, It is possible to quickly generate a three-dimensional view through a modeling program, and then turn it into a plan view. Compared with the conventional artificial plan view and then manually draw the three-dimensional view, the time cost is greatly reduced.

Specifically, the auxiliary quantity calculation is mainly to convert the superimposed complete three-dimensional model diagram into a form form and output it again through a modeling program, and the converted form here can also be defined as a standardized form, but the form is The format, the content of the list, and the data presented are completely different from those to be used for modeling.

Specifically, the auxiliary quantity calculation form generated by the modeling program is shown in Figure 6. The auxiliary quantity calculation form can be the display of the type, unit, quantity and/or amount of engineering components, and it is not limited to these items. Others Quantity calculations or amount calculations related to construction or pipeline construction are included here. The auxiliary quantity calculation form shown as an example in Figure 7 includes specifications, quantities, item header D3, and corresponding quantity data D4 , Can be used as project budget or purchase materials and other follow-up applications.

Specifically, historical data analysis is mainly to store the confirmed and completed three-dimensional model diagram of the pipeline engineering construction and the information contained in the diagram into the database on the management platform.

It needs to be further explained that as time accumulates in the database, the three-dimensional images and related engineering data stored in it also increase. The management platform is used for users or operators to browse, query or refer. If there are similar types of data in the future Project, can copy the project data in the database to the new project, speed up the project and reduce the time of repeated operations.

In addition, the management platform can also analyze the historical data stored in the database to form an analysis chart, as shown in Figure 7. The left side of Figure 7 shows the geometric parameter relationship, and the right side shows the soil parameter relationship. The parameter relationship can be the size, coordinates, etc. between the various pipeline components, and the soil parameters can be the soil characteristics of different sections, etc. The parameters are only examples and are not limited. Through the historical data analysis in the management platform database, you can Learn more about the status of each project, how it can be adjusted in the future, or how to make the project more complete and safer and improve the quality of construction in the future in the same lot or similar soil or similar budget or similar pipeline components.

Furthermore, please continue to refer to FIG. 8, which is a schematic diagram of the management platform displayed according to the authoring method.

Specifically, the display style of the management platform in Figure 9 is only an example, and is not a limitation of this creation. The management platform mentioned in this creation method is mainly an online platform on which projects for different projects can be created and set The person in charge or relevant supervisor of the project, the person in charge or supervisor can modify or review the data or schema in the project.

Specifically, the projects on the management platform can be subdivided into different engineering projects, such as civil engineering, construction, pipelines, machinery, etc. Through the management platform, the progress of each pipeline project can be clearly known, as shown in Figure 8. The completion information displayed in D5 enables the person in charge or supervisor to grasp the progress of the entire project or where the checkpoints are at a glance. At the same time, it improves the efficiency of project management and directly communicates across departments and revises data or diagrams on the management platform. Save a lot of time cost and labor cost of repeated manual drawing.

It is understandable that those with ordinary knowledge in the technical field to which this creation belongs can make various changes and adjustments based on the above examples, which will not be listed here.

Finally, the technical characteristics of this creation and its achievable technical effects are summarized as follows:

First, with the creation of the engineering automation design management device to effectively grasp the progress and current status of the process, through the management platform to quickly understand whether there are barriers or conflicts in different engineering projects, and greatly reduce the time cost of management.

Second, the standardized form specially designed according to this creation not only unifies the chaotic data and data presentation methods between different units or third-party vendors, but also can further quickly produce three-dimensional model diagrams through standardized forms and modeling programs.

Third, the modeling program created according to this creation can not only quickly convert the standardized form to generate a three-dimensional model diagram, but also convert the three-dimensional model diagram into a plan view or graphic information to further provide the construction use of the project, or the budget, specifications, and Statistics of the number.

The above is to illustrate the implementation of this creation through specific specific embodiments. Those with ordinary knowledge in the technical field can easily understand the other advantages and effects of this creation from the content disclosed in this specification.

The above descriptions are only the preferred embodiments of this creation, and are not intended to limit the scope of this creation; all other equivalent changes or modifications made without departing from the spirit of this creation should be included in the following patent scope Inside.

10: Management platform 11: Modeling unit 12: Drawing unit 13: storage unit 14: Inspection unit 20: Standardized form D1: Specification list D2: data D3: Head up D4: Quantity data D5: Completeness information

Figure 1 is a schematic diagram of the engineering automation design management device created according to this invention; Figure 2 is a schematic diagram of the standardized form of the engineering automation design management device created according to this invention; Figure 3 is a schematic diagram of the modeling program of the engineering automation design management device created according to this invention; Figure 4 is a schematic diagram of a three-dimensional model diagram of the engineering automation design management device created according to the present invention; Figure 5 is a schematic plan view of the engineering automation design management device created according to this invention; Figure 6 is a schematic diagram of the auxiliary quantity calculation form of the engineering automation design management device created according to this invention; Figure 7 is a schematic diagram of historical data analysis of the engineering automation design management device created according to this invention; and Figure 8 is a schematic diagram of the management platform of the engineering automation design management device created according to this invention.

10: Management platform

11: Modeling unit

12: Drawing unit

13: storage unit

14: Inspection unit

20: Standardized form

Claims (9)

An engineering automation design management device, including: A management platform, which is used by users after connecting and logging in; A standardized form, the standardized form has a plurality of parameter information, each of the parameter information corresponds to a different design element; A modeling unit is installed in the management platform, the standardized form is imported into the modeling unit, and a three-dimensional model diagram is further generated; and A drawing unit, through the three-dimensional model drawing generated by the modeling unit, generates a plan view or a drawing information table through the drawing unit. The engineering automation design management device according to claim 1, wherein the management platform includes a storage unit for storing the three-dimensional model diagram, the plan diagram, and the diagram type information table. The engineering automation design management device according to claim 1, wherein the management platform includes a checking unit to check whether the three-dimensional model diagrams of the same project and different professions in the management platform conflict with each other. For the engineering automation design management device described in claim 1, wherein a project of a different project can be created on the management platform, and the person in charge of the project can be set, and the person in charge can modify or view the data or schema in the project. The engineering automation design management device according to claim 3, wherein, after inputting the parameter information required for analysis and checking, the checking unit performs a stable checking based on the parameter information, and the stable checking is used To confirm stability. The engineering automation design management device according to claim 1, wherein the modeling program captures the imported parameter information in the standardized form, and constructs the design components corresponding to the parameter information through the building information model The three-dimensional model diagram. The engineering automation design management device according to claim 3, wherein if the superimposed three-dimensional model diagrams have conflicts that need to be corrected, the parameter information in the standardized form is corrected, and the correction is formed through the modeling program again After the three-dimensional model diagram, and the generated three-dimensional model diagram can be converted into a plan view of a specific area according to requirements, the plan view is used for subsequent construction or other operations. The engineering automation design management device according to claim 1, wherein the type, unit, quantity, and/or amount of the engineering components included in the three-dimensional model diagram are calculated through the diagram type information output function of the diagram output unit To form the graph information table. The engineering automation design management device according to claim 2, wherein all the engineering data stored in the storage unit is available for users to browse, query or refer through the management platform. If there are projects of the same type, the database can be Copy the project data in the new project to the new project.

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