KR20210111011A - System for providing visualization service regarding pre-processing and post-processing of open field operation and manipulation solver - Google Patents

Abstract

The present invention relates to a pre-processing and post-processing visualization service providing system of an open-field operation and manipulation (FOAM) solver. An objective of the present invention is to provide computational fluid mechanics software that anyone can easily use through the construction of a graphic user interface for visualizing the pre-processing and post-processing of an open-FOAM solver. The pre-processing and post-processing visualization service providing system of the open FOAM solver comprises: a mesh information generator for receiving input of three-dimensional modelling data of a target object to generate mesh information on the target object in a graphic user interface environment based on the three-dimensional modelling data; a solver selector for selecting a solver of the open FOAM for computational fluid mechanics interpretation work according to setting of the temporal and physical characteristics of the target object; and a graphic user interface environment providing unit including a first graphic user interface for receiving input of output for performing computational fluid mechanics interpretation work of the target object and a setting value with respect to a calculation condition based on the mesh information generated from the mesh information generator and the solver selected by the solver selector.

Description

SYSTEM FOR PROVIDING VISUALIZATION SERVICE REGARDING PRE-PROCESSING AND POST-PROCESSING OF OPEN FIELD OPERATION AND MANIPULATION SOLVER}

An embodiment of the present invention relates to a system for providing a post-processing visualization service of an open form solver.

In general, Computational Fluid Dynamics (CFD) is a method such as FDM (Finite Difference Method), FEM (Finite Element Method) or FVM (Finite Volume Method) for nonlinear partial differential equations describing fluid flow, heat flow, etc. It is a technology that discretizes and converts into algebraic equations, and analyzes phenomena related to fluid flow and heat flow in a numerical analysis method using the algorithm of Numerical Analysis Methods.

Computational fluid dynamics (CFD) is used in various industrial fields, and is typically used in machine design and application fields, plant or engineering fields, and micro-machinery and circuit design fields. It is used for simulations, etc.

In the stage of analysis simulation using computational fluid dynamics (CFD), first, the shape design of the object to be analyzed, and the mesh (Mesh or Grid) generation that configures the minimum unit to be analyzed for the worked shape in the form of a mesh are preprocessed. ) is called

After that, after setting the mesh and analysis conditions, numerical analysis (calculation) is performed. This operation is called solving operation. When the analysis work is completed, the analysis results are stored in each mesh, and these results are visualized so that physical phenomena such as fluid flow and temperature distribution can be recognized by the actual user through post processing.

For computational fluid dynamics (CFD) analysis, researchers or engineers use commercial computational fluid dynamics (CFD) software such as Fluent, CFX, Star-CCM+, or use their own in-house code. are using

However, to use commercial software for computational fluid dynamics (CFD) analysis, it is difficult for users to use it for actual product development or research because it is necessary to pay an expensive cost and to have a high-spec computing environment.

In addition, in the case of commercialized computational fluid dynamics (CFD) software, only limited settings for the solver are supported, so there is a limitation in performing an analysis that accurately reflects the user's intention. Despite these shortcomings, commercial computational fluid dynamics (CFD) analysis software provides a high-level user interface that allows general users to easily access it, and establishes a unified environment that enables the setting of the analysis environment and the integrated analysis of analysis results. to provide it to users.

On the other hand, in the modern computing environment, the development of open source software is not limited to the simple IT field, but is being applied to various industrial fields. Starting with simple library programs, various applications, web services, and even operating systems are being developed as open sources, and this flow is accelerating.

The start of such open source software can be said to be the beginning of the GNU Foundation's General Public License (GPL), which began in the 1990s, and the source code produced based on it was released free of charge and the source code was released by users. The main content is that free use and modification are permitted.

In the field of computational fluid dynamics (CFD), the source of computational fluid dynamics (CFD) software called MFiX, which was developed in the early 2000s at the Energy Technology Research Center in the United States in the early 2000s to support the recent open source environment, is supporting general researchers or developers.

Also, in the case of OpenFOAM, it was developed in the early 1990s and opened as an open source in 2004, securing a large user base among researchers studying computational fluid dynamics (CFD).

However, in most cases of open source computational fluid dynamics (CFD) software, only the code for the analysis solver used in actual analysis is provided, and pre-processing (mesh generation for shape design and analysis) and post-processing (analysis of analysis results and report creation) are provided. ), a separate software must be used. This eventually becomes a factor that limits users' access to open source software.

In addition, OpenFOAM requires inputting set values such as meshes and solvers as text, and there is an inconvenience of having to open and close the viewer dozens to hundreds of times or more. In addition, the viewer is down due to meaningless errors, and viewer settings are required according to the solver, and above all, long-term education and experience are required to use OpenFOAM.

Laid-open Patent Publication No. 10-2019-0113597 (published date: October 08, 2019)

An embodiment of the present invention provides computational fluid dynamics software that anyone can use easily through the construction of a graphical user interface for visualizing the before and after processing of the open form solver.

The system for providing a pre- and post-processing visualization service of an open form solver according to an embodiment of the present invention receives 3D modeling data of a target object, and displays mesh information on the target object based on the input 3D modeling data through a graphical user interface a mesh information generating unit generated in the environment; a solver selector that selects a solver of Open-FOAM (Open-Field Operation And Manipulation) for computational fluid dynamics analysis work according to the temporal and physical characteristics of the target object; and a first graphic for receiving an output for performing computational fluid dynamics analysis of a target object based on the mesh information generated through the mesh information generation unit and a solver selected through the solver selection unit, and setting values for calculation conditions and a graphical user interface environment providing unit including a user interface.

In addition, the graphical user interface environment providing unit, a second graphical user interface for receiving a command for performing computational fluid dynamics analysis of the target object, and computational fluid dynamics analysis of the target object based on the set value and the command A third graphical user interface may be further included to visualize and provide a result.

In addition, the graphical user interface environment providing unit may divide the first graphical user interface, the second graphical user interface, and the third graphical user interface on one screen and simultaneously provide them.

In addition, based on the solver selected through the solver selection unit and the set value and command input through the graphic user interface environment providing unit, a computational fluid dynamics analysis operation on the target object is performed and provided to the third graphical user interface, and the corresponding It may further include an analysis execution and evaluation unit that generates analysis evaluation data for the computational fluid dynamics analysis result of the target object, and visualizes the generated analysis evaluation data as evaluation result report information for the target object.

In addition, the analysis execution and evaluation unit, the evaluation result report information provided in the form of at least one of an image and a moving picture, coordinate information for each area of the target object displayed in the image and the moving picture is set, and the coordinate information When a setting value corresponding to , and command-related data are matched, and the cursor in the image and video is positioned on the coordinate information, a setting value matched to the coordinate information and command-related data may be plotted and displayed.

The mesh information generating unit, the solver selecting unit, and the graphic user interface environment providing unit may further include a language setting unit for providing a multilingual support service for the technical terms provided to the user.

In addition, the first graphical user interface visualizes and outputs the mesh information based on the mesh information generated through the mesh information generation unit and the solver selected through the solver selection unit, but partially selects the visualized mesh information possible, and at least one setting item for the selected mesh area and at least one setting value for each setting item may be selectively displayed when each part of each mesh area is selected.

According to the present invention, it is possible to provide computational fluid dynamics software that anyone can use easily through the construction of a graphical user interface for visualizing the before and after processing of the open form solver.

1 is a block diagram showing the overall configuration of a system for providing a pre- and post-processing visualization service of an open form solver according to an embodiment of the present invention.
2 is a diagram illustrating an example of 3D modeling of a target object and visualization of a mesh shape through a mesh information generator according to an embodiment of the present invention.
3 and 4 are diagrams illustrating various solvers of OpenFOAM provided by the solver selector according to an embodiment of the present invention and details of each solver.
5 is a diagram illustrating a screen configuration provided through a graphical user interface environment providing unit according to an embodiment of the present invention.
6 is a diagram illustrating a functional operation of a first graphical user interface according to an embodiment of the present invention.
7 is a view showing analysis results (images and videos) visualized through the analysis execution and evaluation unit according to an embodiment of the present invention.
8 is a diagram illustrating a method for performing analysis and providing information to an evaluation unit according to an embodiment of the present invention.
9 and 10 are diagrams for comparing analysis results between simulation results according to an embodiment of the present invention and experimental values through a general OpenFOAM solver.

Terms used in this specification will be briefly described, and the present invention will be described in detail.

The terms used in the present invention have been selected as currently widely used general terms as possible while considering the functions in the present invention, but these may vary depending on the intention or precedent of a person skilled in the art, the emergence of new technology, and the like. In addition, in a specific case, there is a term arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, rather than the name of a simple term.

When a part "includes" a certain element throughout the specification, this means that other elements may be further included, rather than excluding other elements, unless otherwise stated. In addition, terms such as "...unit" and "module" described in the specification mean a unit that processes at least one function or operation, which may be implemented as hardware or software, or a combination of hardware and software. .

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily carry out the embodiments of the present invention. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

1 is a block diagram showing the overall configuration of a system for providing a pre- and post-processing visualization service of an open form solver according to an embodiment of the present invention, and FIG. 2 is a three-dimensional modeling of a target object through a mesh information generator according to an embodiment of the present invention. And it is a diagram showing an example of visualization in the form of a mesh, and FIGS. 3 and 4 are diagrams illustrating various solvers of OpenFOAM provided by the solver selection unit according to an embodiment of the present invention and details of each solver. , FIG. 5 is a diagram illustrating a screen configuration provided through a graphical user interface environment providing unit according to an embodiment of the present invention, and FIG. 6 is a diagram illustrating a functional operation of the first graphical user interface according to an embodiment of the present invention 7 is a view showing analysis results (images and videos) visualized through the analysis execution and evaluation unit according to an embodiment of the present invention, and FIG. 8 is information provided by the analysis execution and evaluation unit according to an embodiment of the present invention It is a drawing shown to explain the method.

Referring to FIG. 1 , a system 1000 for providing a post-processing visualization service for an open form solver according to an embodiment of the present invention includes a mesh information generating unit 100 , a solver selecting unit 200 , and a graphic user interface environment providing unit 300 . ), and may further include an interpretation performance and evaluation unit 400 and a language setting unit 500 .

Prior to the description of this embodiment, it may be configured to include a target object shape generator (not shown) as a component for generating 3D modeling data provided to the mesh information generator 100 to be described later. The target object shape generator (not shown) performs a function of designing and generating a 3D shape of the target object desired by the user, for example, an open source CAD program or a commercial or non-commercial design preset by the user. You can design and create 3D modeling data of the target object by calling the program.

The mesh information generating unit 100 may receive 3D modeling data of a target object, and generate mesh information about the target object in a graphic user interface environment based on the input 3D modeling data.

As described above, the mesh information generating unit 100 that visualizes the 3D modeling and the mesh shape in the graphic user interface environment may visualize the propeller modeling data as shown in FIG. 2A , for example. In addition, the mesh information generating unit 100, as shown in (b), (c) and (d) of Figure 2, the mesh creation result for the propeller part, the mesh creation result for the entire calculation area, the mesh for the propeller rotation area The result of writing can be visualized and provided through the screen.

The mesh information generator 100 may generate mesh information on the three-dimensional shape of the corresponding analysis target object by calling an open source grid network generation program or a commercial or non-commercial grid network generation program preset by a user.

The solver selector 200 may select a solver of Open-Field Operation And Manipulation (Open-FOAM) for computational fluid dynamics analysis work according to the setting of temporal and physical characteristics of the target object.

For example, as shown in FIG. 3, the solver selection unit 200 includes a basic solver, a combustion solver, a solver related to a compressive fluid, a solver related to a powder analysis technique, a solver based on a molecular dynamics technique, an electronic analysis related solver, Solver related to financial analysis, solver related to thermal analysis, solver related to incompressible fluid analysis, solver related to Langrangian analysis, solver related to mesh analysis, solver related to multilayer fluid analysis, solver related to structural analysis, solver related to polyphase analysis related to cavity, multiphase analysis related to compressive fluid Multiple solvers folder including analysis solver, polyphase solver with movement, polyphase solver with movement and mixing, polyphase solver with movement and mixing of three or more fluids, and polyphase solver with mixing two liquids. It can be provided selectively in a graphical user interface environment in a format. It can be provided selectively.

In addition, as shown in FIG. 4 , the solver selector 200 includes 'decomposeParDict' (A) for setting how many solvers are divided and calculated, and 'fvSchemes' ( B), a solver such as 'fvSolution' (C) for setting a calculation allowable range during calculation, and a detailed setting file can be selectively provided under a graphical user interface environment.

In addition, the solver selector 200 is a time characteristic setting solver for setting whether a stable state with no change over time or a temporary state in which the past and present states can always be changed by continuously changing input variables, change in pressure Flow characteristics setting solver to set whether it is a compressible or incompressible material (e.g., fluid) whose volume changes according to Mach number setting solver to set whether or not the fluid has Single-phase/multi-phase flow setting solver to determine whether it consists of two or more substances, a thermal condition setting solver to determine whether to set temperature conditions according to the change in fluid motion, gravity or specific direction for fluid motion The gravitational effect setting solver to proceed with the setting when the force of It may further include a mesh change characteristic setting solver to set, and may provide each selectable under a graphical user interface environment.

The graphic user interface environment providing unit 300 may perform a pre-processing operation for computational fluid dynamics analysis of a target object in a graphic user interface (GUI) environment.

To this end, the graphical user interface environment providing unit 300 may include a first graphical user interface 310 , a second graphical user interface 320 , and a third graphical user interface 330 as shown in FIG. 5 . have.

The first graphical user interface 310 analyzes computational fluid dynamics of the target object based on mesh information on the target object generated through the mesh information generating unit 100 and the solver selected through the solver selector 200 . Various setting values for output and calculation conditions for performing work can be input through the graphical user interface environment. As shown in FIG. 5 , the first graphical user interface 310 includes a menu button for setting a set value (case setup) as well as a menu for executing the mesh information generating unit 100 and the solver selecting unit 200 . Buttons (mesh, solver) are provided at the top of the window to facilitate checking between generating mesh information about the target object and information for selecting a solver during work.

The first graphic user interface 310 reads mesh information of the three-dimensional modeling data of the target object, converts it into a preset open source format, and sets the grid format so that it is output on the display screen, depending on the type of fluid. Accordingly, at least one fluid characteristic among temperature, density, specific heat, thermal conductivity, dynamic viscosity, and Prandtl number may be input.

In addition, the first graphic user interface 310 may receive information about a case in which gravity or a force in a specific direction is applied to the movement of the fluid, and turbulence model setting information among the solver information selected by the solver selector 200 . For each turbulence model, different details of variables for analysis can be input for each turbulence model, and for the outermost region of the region where the fluid moves, information on what action to take when the fluid reaches the region and the You can set information (boundary conditions) on how to influence the movement.

In addition, the first graphical user interface 310 may set and receive a discretization scheme for the analysis equation to be solved by the solver, and when calculating the equation to be analyzed, any calculation solver (matrix solver) You can select whether to calculate using

Meanwhile, the first graphic user interface 310 visualizes and outputs mesh information based on the mesh information generated through the mesh information generating unit 100 and the solver selected through the solver selecting unit 200 , but The mesh information may be partially selectively outputted, and at least one setting item for the selected mesh region and at least one setting value for each setting item may be selectively displayed when each part of each mesh region is selected.

For example, as shown in FIG. 6 , the first graphical user interface 310 may visualize and output mesh information about the target object, and the output mesh information may be selected for each area. When each mesh area is selected, setting items for the mesh area and various setting values for output and calculation conditions related to each setting item can be input. More specifically, through the visualized mesh information screen shown on the left of FIG. 6 , the unit setting for the condition value can be checked as shown in a1 of FIG. 6 for the selected setting value, and the input speed (y direction) as shown in a2 You can check the settings for the -5m/s wind input with You can check the setting for the speed of the wall (set to be 0m/s without slipping), and the speed of the propeller like a5 (set to be 0m/s for movement, but the specific rotational speed can be set in a separate file) You can check the setting contents for .

The second graphical user interface 320 may receive a command for performing computational fluid dynamics analysis of the target object.

For example, as shown in FIG. 5 , an execution screen of the terminal mode is output under the split screen of the first graphical user interface 320, and a command required to perform computational fluid dynamics analysis of the target object can be input. have.

The third graphical user interface 330 visualizes and provides a computational fluid dynamics analysis result of a target object based on various input values and commands for setting output and calculation conditions for performing computational fluid dynamics analysis work can do.

For example, as shown in FIG. 5 , the third graphical user interface 330 visualizes and provides the computational fluid dynamics analysis result of the target object on the right side of the split screen of the first and second graphical user interfaces 310 and 320 . This may be done, and such results may be provided together with the screens of the first and second graphic user interfaces 310 and 320 .

The graphical user interface environment providing unit 300 of this embodiment divides the first graphical user interface 310, the second graphical user interface 320, and the third graphical user interface 330 on one screen and provides them at the same time. , it is possible to easily correct errors in the computational fluid dynamics analysis work of the target object by providing the input setting screen and the output result screen separately on one screen as described above.

The analysis execution and evaluation unit 400 performs computational fluid dynamics analysis on the target object based on the solver selected through the solver selection unit 200 and the set value and command input through the graphic user interface environment providing unit 300 . The operation is performed and provided to the third graphical user interface 330, analysis evaluation data for the computational fluid dynamics analysis result of the target object is generated, and the generated analysis evaluation data is visualized to report the evaluation result for the target object. can be created with

For example, as shown in (a) of FIG. 7, the speed of the propeller can be visualized through the propeller surface mark, and the pressure of the propeller can be visualized and displayed through the propeller surface mark as shown in (b) As shown in (c), the speed for the area around the propeller can be visualized through the mid-section display of the target object, and as shown in (d), the propeller can be displayed through the mid-section surface display of the target object as shown in (d). By visualizing and indicating the pressure on the surrounding area, it is possible to provide analysis evaluation data for the computational fluid dynamics analysis result of the target object.

In addition, the analysis execution and evaluation unit 400 provides the evaluation result report information in the form of at least one of an image and a video, but coordinate information for each area of the target object displayed in the image and video is set, and coordinate information When a setting value corresponding to , and command-related data are matched, and a cursor in an image or a video is positioned on the coordinate information, the setting value and command-related data matched with the coordinate information may be plotted and displayed.

For example, as shown in FIG. 8 , coordinate information for each area of evaluation result report information provided in the form of images and videos is allocated, and when an area matched with specific coordinates is selected or the mouse cursor is positioned, the corresponding coordinates It is possible to display the set value corresponding to the area of , and the command-related data by floating on the output screen of the evaluation result report information. In addition, even if it is not specific coordinates, when selecting the output screen of the evaluation result report information provided in the form of images and videos or right-clicking the mouse, various setting information such as various setting values and commands for the evaluation result can be immediately confirmed. may be configured to provide an environment.

The language setting unit 500 is a technical term provided to a user through the mesh information generation unit 100 , the solver selection unit 200 , the graphic user interface environment providing unit 300 , and the analysis execution and evaluation unit 400 . can provide multilingual support service for , and when a user selects a desired language, information on the selected language is retrieved from the language database, and mesh information generation unit 100, solver selection unit 200, and graphical user interface environment are created. By applying to the study 300 and the interpretation performance and evaluation unit 400, it can be set so that the user can proceed with the work in the desired language.

9 and 10 are diagrams for comparing analysis results between simulation results according to an embodiment of the present invention and experimental values through a general OpenFOAM solver.

More specifically, (a) of FIG. 9 is a diagram comparing experimental values and simulation results at 1000, 1500, and 1750 rpm, and FIG. 9 (b) is a torque graph by simulation at 1000, 1500, and 1750 rpm. 10 is a graph comparing a simulation result value according to an embodiment of the present invention and an experimental value through a general OpenFOAM solver.

According to this embodiment, anyone can secure technology for computational fluid dynamics numerical analysis through the software for providing the post-processing visualization service for the OpenFOAM solver.

In addition, access to advanced technology is possible, and by overcoming the limitations of small and medium-sized enterprises (SMEs) engineering, it can help any company in the related technology field to produce better products.

What has been described above is only one embodiment for implementing a system for providing a post-processing visualization service of an open form solver according to the present invention, and the present invention is not limited to the above embodiment, but as claimed in the claims below. Likewise, without departing from the gist of the present invention, it will be said that the technical spirit of the present invention exists to the extent that various modifications can be made by anyone with ordinary knowledge in the field to which the invention pertains.

1000: Open form solver post-processing visualization service providing system
100: mesh information generation unit
200: solver selection
300: Graphical user interface environment providing unit
310: first graphical user interface
320: second graphical user interface
330: third graphical user interface
400: analysis performance and evaluation unit
500: language setting unit

Claims (6)

a mesh information generator that receives 3D modeling data of a target object and generates mesh information about the target object in a graphical user interface environment based on the input 3D modeling data;
a solver selector that selects a solver of Open-FOAM (Open-Field Operation And Manipulation) for computational fluid dynamics analysis according to the temporal and physical characteristics of the target object; and
A first graphic user for receiving an output for performing computational fluid dynamics analysis of a target object and setting values for calculation conditions based on the mesh information generated through the mesh information generating unit and a solver selected through the solver selection unit A system for providing a post-processing visualization service of an open form solver, characterized in that it comprises a graphical user interface environment providing unit including an interface.
According to claim 1,
The graphic user interface environment providing unit,
A second graphical user interface for receiving a command for performing computational fluid dynamics analysis of the target object, and a third graphical user who visualizes and provides the computational fluid dynamics analysis result of the target object based on the set value and the command Post-processing visualization service providing system of the open form solver, characterized in that it further comprises an interface.
3. The method of claim 2,
The graphic user interface environment providing unit,
The system for providing a post-processing visualization service for an open form solver, characterized in that the first graphical user interface, the second graphical user interface, and the third graphical user interface are divided on one screen and provided at the same time.
3. The method of claim 2,
Based on the solver selected through the solver selection unit and the set value and command input through the graphic user interface environment providing unit, a computational fluid dynamics analysis operation is performed on the target object and provided to the third graphical user interface, and the target object of the open form solver, characterized in that it further comprises an analysis execution and evaluation unit that generates analysis evaluation data for the computational fluid dynamics analysis result of Post-processing visualization service provision system.
According to claim 1,
Post-processing visualization service of the open form solver, characterized in that it further comprises a language setting unit for providing a multilingual support service for technical terms provided to a user through the mesh information generation unit, the solver selection unit, and the graphic user interface environment providing unit delivery system.
According to claim 1,
The first graphical user interface,
Based on the mesh information generated through the mesh information generation unit and the solver selected through the solver selection unit, the mesh information is visualized and output, but the visualized mesh information is partially selectable, and a portion of each mesh area When a star is selected, at least one setting item for the selected mesh area and at least one setting value for each setting item are selectively displayed.

Images