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Analysis software Product List

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[Example] Model creation and structural analysis in bioengineering.

[Example] Model creation and structural analysis in bioengineering.

"VOXELCON" is a structural analysis software that directly models STL data from CT and CAD for analysis and measurement purposes.

In the field of bioengineering, there is no design data available, so it is necessary to measure the actual object and create an analysis model. By using image-based analysis supported by VOXELCON, modeling can be performed from CT scan images of the actual object, allowing for faithful modeling that eliminates human error and significantly reduces the effort required for modeling. *For more details, please refer to the related links or feel free to contact us.

  • Structural Analysis
  • Other analyses
  • Contract Analysis

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[Case Study] Stress Analysis of a Crankshaft through Reverse Engineering

[Case Study] Stress Analysis of a Crankshaft through Reverse Engineering

"VOXELCON" is a structural analysis software that directly models STL data from CT and CAD for analysis and measurement purposes.

Model Creation and Structural Analysis from CT Images We will introduce an example of reverse engineering that measures the shape of a product (physical object) and uses it for direct analysis. Generally, creating a model for analysis from X-ray CT scan images requires a very labor-intensive process of generating a CAD model from the extracted surface. However, at VOXELCON, we can directly create a surface model from the image data of an X-ray CT scanner and apply boundary conditions directly on the surface model, allowing for voxel analysis without additional steps. This significantly reduces the labor involved in reverse engineering. Here, we will present an example of creating a model from artificially generated tomographic images, simulating the tomographic images from an X-ray CT scanner, and performing static stress analysis. *For more details, please refer to the related links or feel free to contact us.*

  • Structural Analysis
  • Other analyses
  • Contract Analysis

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[Case Study] Evaluation of Macro Physical Properties Using Actual Data

[Case Study] Evaluation of Macro Physical Properties Using Actual Data

"VOXELCON" is a structural analysis software that directly models STL data from CT and CAD for analysis and measurement purposes.

In materials design, investigating the macroscopic mechanical properties of porous materials such as ceramics and foamed metals, as well as composite materials represented by FRP, is very important. When actual samples are available, it is generally possible to measure them through experiments; however, depending on the properties of the materials and the condition of the samples, experiments may not always be easy. Here, we will introduce an example of calculating the macroscopic physical properties of a sample by analyzing the tomographic images obtained from scanning an actual sample with a micro X-ray CT scanner, using VOXELCON's image-based modeling and homogenization analysis functions. Note: The physical property values of the original materials that make up the porous materials and composite materials are assumed to be obtained in advance. *For more details, please refer to the related links or feel free to contact us.

  • Structural Analysis
  • Other analyses
  • Contract Analysis

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[Example] Analysis of Warping in Electronic Circuit Boards

[Example] Analysis of Warping in Electronic Circuit Boards

"VOXELCON" is a structural analysis software that directly models STL data from CT and CAD for analysis and measurement purposes.

At VOXELCON, we perform thermal stress analysis using the temperature distribution from steady-state heat conduction analysis as a thermal load, allowing for easy weakly coupled analysis of steady-state heat conduction and thermal stress. Here, we will introduce an example of warping analysis of an electronic substrate using a simple model. *For more details, please refer to the related links or feel free to contact us.*

  • Structural Analysis
  • Other analyses
  • Contract Analysis

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[Example] Calculation of Equivalent Stiffness of Sandwich Structure Panels

[Example] Calculation of Equivalent Stiffness of Sandwich Structure Panels

"VOXELCON" is a structural analysis software that directly models STL data from CT and CAD for analysis and measurement purposes.

The sandwich structure, which consists of a core material sandwiched between surface panels to create a unified structure, is widely used in various fields as it offers a lightweight design with high bending stiffness. However, in cases where the core is not made of a single material but is composed of multiple materials, the equivalent properties of the sandwich structure cannot be determined using simple laminate theory. In this example, we will demonstrate how to calculate the equivalent property values of a core made of composite materials using VOXELCON's homogenization analysis function, and perform bending analysis of the sandwich structure using a simplified model based on the obtained material property values. *For more details, please refer to the related links or feel free to contact us.*

  • Structural Analysis
  • Other analyses
  • Contract Analysis

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[Example] Equivalent permeability coefficient and micro flow velocity distribution of porous media

[Example] Equivalent permeability coefficient and micro flow velocity distribution of porous media

"VOXELCON" is a structural analysis software that directly models STL data from CT and CAD for analysis and measurement purposes.

With the increasing use of composite materials and porous materials, the importance of evaluating the properties of their microstructures is growing. In this example, we will introduce the calculation of the equivalent permeability coefficient and micro velocity distribution of a porous body as an example of evaluating the flow characteristics of microstructures using the homogenization method of VOXELCON. *For more details, please refer to the related links or feel free to contact us.*

  • Structural Analysis

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[Example] Topology optimization of large-scale models

[Example] Topology optimization of large-scale models

"VOXELCON" is a structural analysis software that directly models STL data from CT and CAD for analysis and measurement purposes.

VOXELCON is equipped with topology optimization using the level set method. In this topology optimization, a target volume is set, and a shape is sought that maximizes stiffness (minimizes displacement at load points) under that volume constraint. Since structural optimization involves repeated structural analysis, the computation time can be very long. Additionally, the structural analysis specialized for voxels is characterized by good parallelization efficiency and low memory consumption, allowing for analysis of large-scale problems in a realistic time frame. The topology optimization feature also supports parallel execution on GPUs, so we will also introduce the computation time. *For more details, please refer to the related links or feel free to contact us.*

  • Structural Analysis

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[Case Study] Shape optimization to improve natural frequency ★ Detailed materials available

[Case Study] Shape optimization to improve natural frequency ★ Detailed materials available

Control the natural frequency while considering the MAC value. Utilize parallelization to handle large-scale models in a short time.

By changing the shape, we improve the natural frequency and resonance frequency. Additionally, we have added conditions to allow for die-cutting in accordance with manufacturing requirements. In recent years, the performance of PCs has increased, and the scale of models required for finite element analysis has also grown larger. In such cases, utilizing parallelization allows for significant time reduction. This time, we performed shape optimization of a large-scale model with over one million nodes using parallelization. 【Analysis Model】 ■ Elements: Tetrahedral second-order elements ■ Number of elements: 653,931 ■ Number of nodes: 1,026,428 <Related Keywords> - Rib shape - Matching while considering MAC values - Controlling eigenvalues *For more details, please refer to the PDF document or feel free to contact us.

  • Structural Analysis
  • Contract Analysis
  • Other analyses

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[Case Study] Shape Optimization of Spot Welded Flat Plate Stiffeners ★ Detailed Materials Available

[Case Study] Shape Optimization of Spot Welded Flat Plate Stiffeners ★ Detailed Materials Available

Shape optimization of quadrilateral shell elements! It is also possible to optimize the thickness simultaneously!

As an example of shape optimization analysis for shell elements, we will focus on the reinforcing material of a square plate assumed to be the "center pillar" that constitutes the body of a car. "OPTISHAPE-TS" has a function that maintains the cross-sectional shape, allowing for the avoidance of complex cross-sectional shapes of the member during the shape optimization process. In the shape optimization process, RBE3 elements and their surrounding elements are automatically treated as spot welds, and constraints are set so that only rigid body motion is possible in those areas. In other words, while the position of the spot welds may move, the size and shape of the welds are constrained to remain unchanged. [Analysis Model] ■ Elements: Quadrilateral shell elements ■ Number of nodes: 47,425 ■ Number of elements: 46,440 *For more details, please refer to the PDF document or feel free to contact us.

  • Structural Analysis

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Example: Warpage countermeasures for connectors in injection molding.

Example: Warpage countermeasures for connectors in injection molding.

By collaborating with 3D TIMON, we automatically adjust the thickness of solid element models, thereby suppressing warping deformation.

We will introduce a case where warping was minimized by changing the thickness of solid elements. The analysis was conducted using the "basis vector method," which modifies the shape by moving the nodes of the finite element model without using CAD. Several patterns (basis vectors) of the desired shape were prepared from the initial model and combined. As a result of the optimization, the sum of squares of warping improved by 33% to 4.9480e-004 compared to the initial shape, and the maximum warping amount (mm) improved by 12% to 3.8607e-002. [Case Overview] ■ Optimization Conditions - Design Variables: Thickness A, B - Sampling: Initially LHS 20 points, Approximate optimal solution + 10 recommended points - Approximate Model: CRBF (Convolutional RBF) ■ Analysis: Basis Vector Method *For more details, please refer to the PDF document or feel free to contact us.

  • Other analyses

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Example: Silent Design of Electromagnetic Field Reactor

Example: Silent Design of Electromagnetic Field Reactor

By integrating various software such as CAD, magnetic field analysis, and acoustic analysis, a wide range of optimization can be achieved!

This example introduces the integration of three software programs to reduce noise without compromising the electrical performance of a reactor. First, the general-purpose parameter optimization software "AMDESS" rewrites the VB script file of the 3D CAD software "SolidWorks" with trial dimensions and modifies the model dimensions. Next, the electromagnetic field analysis software "JMAG" communicates with "SolidWorks" to import the CAD model, performs meshing and analysis, and "AMDESS" extracts responses from the analysis results of "JMAG." As a result, starting from 30 samples using Latin hypercube sampling, a 31% reduction in sound pressure was achieved through six updates of the response surface. 【Optimization Conditions】 ■ Design Variables: Core dimensions D1 to D4 ■ Objective Function: Minimization of reactor sound pressure ■ Constraint Functions: Inductance greater than or equal to the initial value, core volume less than or equal to the initial value ■ Approximation Model: RBF *For more details, please refer to the PDF document or feel free to contact us.

  • Other analyses
  • Contract Analysis
  • simulator

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Example: Injection Molding - Search for Gate Position Considering Warpage Countermeasures and Robust Design

Example: Injection Molding - Search for Gate Position Considering Warpage Countermeasures and Robust Design

We will explore design proposals that balance anti-sledding measures and robustness in collaboration with 3D TIMON.

Robustness represents the strength (small variation) against changes in the environment or situation and is an important evaluation criterion that affects yield in actual production. "AMDESS" can provide a virtual variation to the approximation model, allowing for the evaluation of this robustness. Here, we will introduce a case of gate position optimization where "AMDESS" and "3D TIMON" are linked, and robustness is evaluated after the usual optimization. [Contents] ■ Overview ■ Analysis Model ■ Optimization Conditions ■ Optimization Results ■ Variation Evaluation ■ Discussion *Detailed information about the case can be viewed through the related links. For more information, please feel free to contact us.

  • Structural Analysis

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[Technical Column] The Theory of OPTISHAPE-TS: "What is the Gradient Method?"

[Technical Column] The Theory of OPTISHAPE-TS: "What is the Gradient Method?"

A brief explanation of what gradient methods are, based on the formulation of optimization problems!

In the previous articles, we explained the "H1" in the H1 gradient method. I hope you have deepened your understanding of the concept of function spaces. From this time onward, I would like to explain the remaining "gradient methods" over several articles. To begin with, this article will discuss an overview of gradient methods. Please feel free to download and take a look. [Contents] ■ Episode 14 What is the H1 Gradient Method? Part 7 "What is a Gradient Method?" *For more details, please refer to the PDF materials or feel free to contact us.

  • Structural Analysis

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The theory of OPTISHAPE-TS: The relationship between three functions and H1.

The theory of OPTISHAPE-TS: The relationship between three functions and H1.

A subtle relationship with three functions that often appear in the field of engineering! Introducing in a column.

In the previous discussion, we explained norms and inner products in function spaces. Finally, to help you gain a deeper understanding of the concept of function spaces, we will describe the subtle relationships between three functions that frequently appear in the field of engineering (for example, control engineering and vibration engineering). Please feel free to download and take a look. [Contents] ■ Episode 13: What is the H1 Gradient Method? Part 6 "The Relationship Between Three Functions and H1" *For more details, please refer to the PDF document or feel free to contact us.

  • Structural Analysis

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[Technical Column] The Theory of OPTISHAPE-TS: Infinite Dimensions and Function Spaces

[Technical Column] The Theory of OPTISHAPE-TS: Infinite Dimensions and Function Spaces

To deepen your understanding of H1, we will explain norms and inner products in function spaces!

Last time, I explained the completeness of the space. Since H1 is a function space, this time I will explain the norms and inner products in function spaces to deepen your understanding of H1. Please feel free to download and take a look. 【Contents】 ■ Episode 12: What is the H1 Gradient Method? Part 5 "Infinite Dimensions and Function Spaces" *For more details, please refer to the PDF document or feel free to contact us.

  • Structural Analysis

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