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Simulation Software(Test) - List of Manufacturers, Suppliers, Companies and Products

Last Updated: Aggregation Period:Oct 15, 2025~Nov 11, 2025
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Simulation Software Product List

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Optimization of Marine Propeller Blade Shape Using OpenFOAM

Optimization of Marine Propeller Blade Shape Using OpenFOAM

The blades used for calculations can be created using the "Generic Blade" feature of CAESES.

One of the advantages of CAESES is its optimization design through an automation system connected to CFD software. This article introduces the blade shape optimization of marine propellers using OpenFOAM and CAESES, which is currently in use. In CAESES, in addition to methods for designing parametric 2D and 3D models, it is also possible to connect with various external software. *For more details, you can view the related links. For further information, please download the PDF or feel free to contact us.*

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  • Software (middle, driver, security, etc.)
  • Other analyses

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Optimization of globe valve shape

Optimization of globe valve shape

The purpose is to improve and investigate the performance of globe valves, connecting the cloud-based CFD solver SimScale with CAESES!

CAESES has been conducting optimization calculations for various types of valves and has implemented projects in collaboration with various companies. In this context, we would like to introduce one of the newly conducted projects, "Shape Optimization of a Globe Valve." This project was carried out in cooperation with GEMÜ Gebr. Müller Apparatebau, a German valve manufacturer and a global company specializing in aseptic valves, and SimScale, a leading engineering simulation company. *For more detailed information, please refer to the related links. You can download the PDF for more details or feel free to contact us.*

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  • Structural Analysis
  • Other CAD
  • valve

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[Example] Tensile test of resin and copper interface in MaterialsStudio

[Example] Tensile test of resin and copper interface in MaterialsStudio

Introduction of tensile test case for resin and copper interface in Materials Studio.

Case Study Utilizing "Materials Studio" ◇ It is possible to observe the movement of molecules during tensile testing. It is possible to determine the force required to lift epoxy resin with a crosslink density. Additionally, it is possible to determine the crosslinked structure in an amorphous state. 【Product Features】 ■ Ideal for "Materials Informatics" ■ Simulation software that streamlines material development Available for use by those engaged in research, development, design, and manufacturing across various industries. ■ Helps in the development of new materials more efficiently and easily. ■ Supports various types of materials. ■ All tasks, including crystal structure creation, calculation condition settings, and calculation result display, can be performed on a single GUI screen. *For more details, please feel free to contact us. Wavefront Co., Ltd. Sales Department MAIL: sales@wavefront.co.jp

  • others
  • plastic
  • Other metal materials

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Optimization of catalytic converter performance using CAESES.

Optimization of catalytic converter performance using CAESES.

Optimization of the duct of the catalytic converter using CAESES!

Designing engine components for automobiles often involves considering many constraints, making it a challenging task within development design work. One example is the duct located just before the catalytic converter. Due to space constraints, this component is often designed to be bent quite sharply, which makes it difficult to ensure that the flow distribution is sufficiently uniform. In other words, if the flow characteristics of the catalytic converter are poor, there is a possibility that performance will decrease and emissions will increase. In this case, optimization of the duct for the catalytic converter will be performed using CAESES. *For more details, please refer to the related links. For further information, feel free to download the PDF or contact us.*

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  • Other analysis software

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Collaboration between CAESES and OpenFOAM in Blade Shape Optimization

Collaboration between CAESES and OpenFOAM in Blade Shape Optimization

Introduction to parameter control of script files and optimization execution during OpenFOAM integration!

This article focuses on the software connection in the shape optimization process using OpenFOAM and CAESES. The application targeted is a propeller blade, and the connection between external software and CAESES can be established quickly, allowing for the rapid initiation of automatic optimization and design considerations for the blade. The collaboration between CAESES and OpenFOAM has been utilized in various cases, and tutorials and sample files are available within CAESES. This collaborative system using open-source software is highly efficient and can greatly benefit from optimization calculations. *For more detailed information, please refer to the related links. For further details, you can download the PDF or feel free to contact us.*

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  • Other analyses
  • Image analysis software

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[Example] Polymer/Metal Surface Interactions in MaterialsStudio

[Example] Polymer/Metal Surface Interactions in MaterialsStudio

Introduction of interaction examples between "polymer/metal surfaces" in Materials Studio.

Case Study Utilizing "Materials Studio" ◇ The interaction at interfaces in polymers is important in a wide range of product fields. For example, adhesives, coatings, composite materials, films, lubricants, paints, and printing inks. The properties at interfaces are of interest to researchers in these fields. Utilizing one of the modules, "Forcite Plus," helps to understand the structure of interfaces. In this case study, we simulated the interaction between alumina (Al2O3) and polyparanitrostyrene. 【Features】 ■ Also optimal for "Materials Informatics" ■ Simulation software that streamlines material development It can be used by those engaged in research, development, design, and manufacturing across various industries. ■ Helps in the development of new materials more efficiently and easily. ■ Supports various types of materials. ■ All tasks, including crystal structure creation, calculation condition setting, and calculation result display, can be performed on a single GUI screen. *For more details, please feel free to contact us. Wavefront Co., Ltd. Sales Department MAIL: sales@wavefront.co.jp

  • others
  • plastic
  • Other metal materials

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Dimensional reduction of hull shape using principal component analysis in CAESES.

Dimensional reduction of hull shape using principal component analysis in CAESES.

Introducing the dimensional reduction function based on the drag optimization of KCS ships!

To optimize the hydrodynamic performance of the hull using the parametric modeling and optimization software CAESES, we first extract design variables related to the deformation of the hull's variable geometry. By increasing the number of design variables in this process, we can obtain a wider variety of deformation shapes, which in turn increases the likelihood of achieving better hull design proposals. However, the number of computational cases required for simulations (such as CFD analysis) increases exponentially (recommended number of cases S = 2^N, where N is the number of design variables), leading to significantly larger computational and time costs. To address this issue, CAESES5 offers a dimensionality reduction feature based on Principal Component Analysis (PCA) methods. *For more detailed information, please refer to the related links. For further details, feel free to download the PDF or contact us.*

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  • Other analyses

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Optimization design of assistive artificial hearts

Optimization design of assistive artificial hearts

Introducing the parametric model of the pump model and the evaluation of H-Q (Head-Flow) and T-Q (Torque-Flow)!

This article introduces the research and development of a ventricular assist device conducted by researchers at the Penn State College of Medicine using CAESES and CONVERGE. The goal of this research is to reduce the risk of adverse events such as hemolysis, degradation of von Willebrand factor, and thrombosis while minimizing the size of the pumps used in artificial hearts. To efficiently create a wide range of pump designs, CAESES has parameterized the flow path shape of the pump. *For more detailed information, you can view the related links. For further details, please download the PDF or feel free to contact us.*

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  • Structural Analysis
  • Other analysis software
  • Other Pumps

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Optimization of vessels

Optimization of vessels

The total hull resistance obtained after parametric modeling, CFD analysis, and optimization processing was reduced by 2 to 3%.

CAESES's hull parametric modeling, when combined with CFD software, facilitates the study of hull shapes (reducing resistance) and enables the design to optimize hull performance. The hull shape, particularly the forward shape, has a significant impact on hull resistance, making shape optimization crucial. With CAESES, hulls can be easily parameterized, allowing for straightforward adjustments to the hull shape. By generating multiple shape patterns and combining them with analysis tools, designs can be optimized according to various optimization objectives. *For more detailed information, please refer to the related links. For further details, you can download the PDF or feel free to contact us.*

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  • Software (middle, driver, security, etc.)
  • Other analyses

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[Case] Electrode Expansion in Charging and Discharging of MaterialsStudio

[Case] Electrode Expansion in Charging and Discharging of MaterialsStudio

"Materials Studio" can perform battery characteristic calculations. [Case Introduction] We will present examples of electrode expansion during charging/discharging.

◇Introduction of Electrode Expansion Cases in Charging/Discharging - Here, we are calculating and plotting the volume of the electrode to observe changes in the active material. - It is believed that the anode experiences an increase in volume due to the weakening of the intercalation bonds in the graphite layers caused by Li intercalation. - In the cathode, the volume increases with the decrease of Li ions. 【Product Features】 ■ Also optimal for "Materials Informatics" ■ Simulation software that streamlines material development Available for use by those engaged in research, development, design, and manufacturing across various industries. ■ Helps in the development of new materials more efficiently and easily. ■ Compatible with various types of materials. ■ All tasks, including crystal structure creation, calculation condition setting, and calculation result display, can be performed on a single GUI screen. *For more details, please feel free to contact us. Wavefront Corporation Sales Department MAIL: sales@wavefront.co.jp

  • others
  • plastic
  • Other metal materials

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[Example] MaterialsStudio semiconductor band gap calculation

[Example] MaterialsStudio semiconductor band gap calculation

"Materials Studio" is also useful for semiconductor material development. [Example] We will guide you through the band gap calculation of semiconductor GaAs.

◇Introduction of Band Gap Calculation Example for Semiconductor GaAs - GaAs, a semiconductor, is used in transistors and has the characteristic of high electron mobility. - The energy level between the valence band and the conduction band is called the band gap. - By investigating the band gap, characteristics such as electrical conductivity and conversion efficiency can be understood. - Using quantum mechanical calculations, it is also possible to investigate semiconductors that are attracting attention as materials. 【Product Features】 ■ Also optimal for "Materials Informatics" ■ Simulation software that streamlines material development Available for use by those engaged in research, development, design, and manufacturing across various industries. ■ Helps in the development of new materials more efficiently and easily. ■ Supports various types of materials ■ All tasks, including crystal structure creation, calculation condition setting, and calculation result display, can be performed on a single GUI screen. *For more details, please feel free to contact us. Wavefront Corporation Sales Department MAIL: sales@wavefront.co.jp

  • others
  • plastic
  • Other metal materials

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[Example] Optical property calculation of coumarin using MaterialsStudio

[Example] Optical property calculation of coumarin using MaterialsStudio

Introduction of a simulation case for calculating the optical properties of coumarin using Materials Studio.

Case Study Utilizing "Materials Studio" ◇ Coumarin molecules are a type of aromatic compound derived from plants, represented by cherry leaves. Additionally, it is known that coumarin molecules are optically active. By utilizing one of the modules, "DMOL3," we can gain insights into optical properties in such cases. In this case study, we simulated the optical properties of coumarin molecules in both vacuum and aqueous solvent. Furthermore, the consideration of the solvent was conducted using the COSMO solvent model. 【Features】 ■ Also optimal for "Materials Informatics" ■ Simulation software that streamlines material development Available for use by those engaged in research, development, design, and manufacturing across various industries ■ Helps in the development of new materials more efficiently and easily. ■ Supports various types of materials ■ Allows for the creation of crystal structures, setting of calculation conditions, and display of calculation results all on a single GUI screen. *For more details, please feel free to contact us. Wavefront Corporation Sales Department MAIL: sales@wavefront.co.jp

  • others
  • plastic
  • Other metal materials

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Optimization of the shape of the volute and diffuser of a centrifugal compressor.

Optimization of the shape of the volute and diffuser of a centrifugal compressor.

For shape creation, we use CAESES, and for mesh model creation and CFD analysis, we use products from NUMECA!

At the Technical University of Darmstadt in Germany (Institute of Gas Turbines and Aerospace Propulsion), research was conducted on the automatic optimization of the volute of centrifugal compressors and vane diffusers. This project was carried out in collaboration with NUMECA, a German company, and Kompressorenbau Bannewitz GmbH (KBB), a turbo machinery manufacturer. CAESES was used for shape creation, while NUMECA's products were utilized for mesh model creation and CFD analysis. In CAESES, a parametric model was created that allowed for variations in the cross-sectional shape and area distribution of the volute. For the diffuser, a non-axisymmetric design was implemented, enabling quick shape transformations by varying the misalignment angle, blade twist, chord length, pitch, and rotation through a parametric model. *For more detailed information, please refer to the related links. You can download the PDF for more details or feel free to contact us.*

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  • Structural Analysis
  • Other analysis software

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Maritime and Offshore design

Maritime and Offshore design

Processing in multiple fields within a single environment! Easy handling of large-scale and complex models.

BETA CAE Systems' software package provides simulation solutions that cover the advanced needs of the maritime industry. The advanced pre-processing and post-processing capabilities of our products significantly contribute to cost reduction in research and design processes. The rich tools and methods elevate simulation analysis in maritime testing to a new level, helping to understand the behavior of models. 【Features】 ■ Process automation ■ Geometry cleanup ■ Shell and volume meshing ■ Boundary layer mesh ■ Interoperable deck *For more details, please refer to the PDF materials or feel free to contact us.

  • Other analyses

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Welding deformation and residual stress simulation software 'ASU/WELD'

Welding deformation and residual stress simulation software 'ASU/WELD'

A series of welding distortion and residual stress simulation software that can be utilized to improve the efficiency of jig design. We will introduce examples of welding distortion based on clamping conditions.

The "ASU/WELD" series visualizes the effects of welding thermal distortion in advance and guides the welding process, enabling reductions in prototype costs and shortening of delivery times. ■ Product Introduction - "ASU/WELD-Express," a software for analyzing inherent distortion in a short time. - "ASU/WELD-Master," a thermal elastic-plastic analysis software capable of detailed evaluation of welding deformation and residual stress. ■ Challenges and Issues Faced by Welding Engineers - Shortening delivery times and reducing man-hours in the welding process. - Product dimension defects due to welding distortion. - Decreased structural strength due to residual stress. This is recommended for those facing the above challenges. For detailed product information, please download the catalog or contact us.

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  • Other analyses
  • Analysis Services
  • Image analysis software

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