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

Last Updated: Aggregation Period:Sep 03, 2025~Sep 30, 2025
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Simulation Software Product List

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Optimization of axial fans using TCFD and CAESES.

Optimization of axial fans using TCFD and CAESES.

The goal of the optimization calculation is to maximize fan efficiency at specific flow rates and increase airflow!

In this case, we will introduce the automatic optimization workflow for axial fan rotor blades developed by CFDSupport, the creator of TCAE, and FRIENDSHIP SYSTEMS, the creator of CAESES. The project began in response to requests from designers and manufacturers who have basic designs for axial fans and wish to improve existing products into more optimal shapes. *For detailed content of the article, you can view it through the related links. For more information, please download the PDF or feel free to contact us.*

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  • Structural Analysis
  • fan
  • Other analysis software

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Optimization of drone propeller shape

Optimization of drone propeller shape

Providing the right products to customers! Introducing the benefits and applications of CAESES at Parrot.

The French company Parrot, which specializes in the design and development of drones, uses CAESES for the design of drone propellers. The reason Parrot's engineers, who are experts in the drone market, adopted CAESES is to speed up the design process and provide customers with even more suitable products. Here, we will introduce the benefits and applications of CAESES at Parrot. *For detailed information, you can view the related links. For more details, please download the PDF or feel free to contact us.*

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  • Structural Analysis
  • Software (middle, driver, security, etc.)

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Collaboration feature of CONVERGE and CAESES using the intake port.

Collaboration feature of CONVERGE and CAESES using the intake port.

Supporting development design operations! Introducing features that can be effectively utilized.

The optimization calculation software CAESES and the thermal fluid analysis software CONVERGE work together as a collaborative optimization system aimed at shape optimization and investigating the effects of design variables, providing support to engineers in the design and development field. In this article, we will introduce the functions that can be effectively utilized in CAESES when collaborating with CONVERGE, using intake port models and piston models. *For detailed content of the article, please refer to the related links. For more information, feel free to download the PDF or contact us.

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  • Other analysis software

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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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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 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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Automatic Optimization using Adjoint Flow Solvers

Automatic Optimization using Adjoint Flow Solvers

It is possible to efficiently obtain optimal candidate geometry that can be directly supplied to the downstream CAD design process!

At FRIENDSHIP SYSTEMS, the developer of the CAD and optimization software CAESES, automatic optimization calculations were performed based on the shape sensitivity calculated by Adjoint Flow Solvers. The open-source optimization toolkit Dakota, integrated into CAESES, provides optimization methods that can directly accept gradient information obtained by combining shape sensitivity with CAD model parameters as input data. Based on this information, the algorithm selects parameters for design candidates created by CAESES, and calculations are performed using Adjoint Flow Solvers. *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 analysis software

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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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Optimization Case of Centrifugal Compressor Impeller Using CAESES

Optimization Case of Centrifugal Compressor Impeller Using CAESES

By constructing a parametric model, it is also possible to optimize the entire compressor model!

Centrifugal compressors are compact yet feature a high pressure ratio, and they are widely used in systems in the fields of aircraft and marine vessels. Impeller design is a crucial design aspect of centrifugal compressors and has a significant impact on compressor performance. In this case, we conducted automatic performance optimization using CAESES combined with CFD tools on an existing centrifugal compressor impeller model. *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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  • Centrifugal concentrator

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Reduction of CO2 emissions through hull shape optimization.

Reduction of CO2 emissions through hull shape optimization.

Introducing how much the annual CO2 emissions have been reduced by utilizing CAESES!

FRIENDSHIP SYSTEMS, the developer of CAESES, has contributed to the reduction of energy consumption and CO2 emissions not only through support for the improvement of turbo machinery and engine-related parts but also for vessels. This article will introduce the experiences in design and improvement for CO2 emission reduction and how much annual CO2 emissions have been reduced by utilizing CAESES. *For detailed content of the article, please refer to the related link. For more information, feel free to download the PDF or contact us.

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  • Other analyses
  • Modeler

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[Example] Efficient Optimization through Morphing 'CAESES'

[Example] Efficient Optimization through Morphing 'CAESES'

Only the modified parts of the existing shape are defined by parameters! Various shapes can be created.

We will introduce efficient optimization using morphing with "CAESES," which we provide. It is mainly used in the shipbuilding and maritime industry, but the majority of users focus on full parametric modeling. In morphing (partial parametric modeling), the deformation of imported existing geometry is performed. Therefore, only the modified parts of the existing shape are defined by parameters, allowing for the creation of various shapes. 【Previous Morphing Features】 ■ Shift transformations ■ Lackenby shift ■ Free-Foam deformation (FFD) ■ Cartesian shifts ■ Spot transformations *For more details, please download the PDF or feel free to contact us.

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  • Other analysis software

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Design of a centrifugal water pump

Design of a centrifugal water pump

Implementing the design process of a centrifugal water pump that maximally utilizes the capabilities of CAESES!

Centrifugal pumps are commonly used in industrial and household applications because their design, manufacturing, and maintenance are relatively simple. They also have the advantage of being efficient and easily adaptable to various sizes. Students from the Department of Transportation Systems at the Technical University of Berlin implemented the design process of a centrifugal water pump that maximizes the capabilities of CAESES as part of an internship project at FRIENDSHIP SYSTEMS, the developer of CAESES. *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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  • Structural Analysis
  • Other pumps

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Optimization of the rear wing shape

Optimization of the rear wing shape

Utilizing CAESES for the optimization of the rear wing shape attached to racing cars!

FRIENDSHIP SYSTEMS, the developer of CAESES, has actively supported student racing teams such as FaSTTUBe and the Ryerson Formula Racing Team. Among these, CAESES was utilized for the optimization of the rear wing shape of racing cars in the Formula Student Germany (FSG) contest, which gathers students from all over Germany. This case study will introduce the optimization of the rear wing and its results. *For more detailed information, please refer to the related links. For further inquiries, feel free to download the PDF or contact us.*

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  • Other analysis software

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Aerodynamic optimization of vertical axis wind turbines

Aerodynamic optimization of vertical axis wind turbines

CAESES can perform optimization calculations and support users in their design tasks!

In this case, we will introduce the optimization calculations for vertical axis wind turbines. FRIENDSHIP SYSTEMS, the developer of the optimization design system CAESES, investigated the aerodynamic behavior of vertical axis wind turbines using the mesh generation software Pointwise. As a first initiative, FRIENDSHIP SYSTEMS connected the automatic mesh generation by Pointwise with CAESES and executed a method to optimize vertical axis wind turbines in 2D using various tools, including analysis 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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  • Turbine

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Propeller design of Caterpillar Propulsion

Propeller design of Caterpillar Propulsion

Execute tasks such as setting up the blade model and generating individual dynamic 2D drawings!

Caterpillar Propulsion has implemented CAESES for the design of propeller blades. When we started on a project basis, the overall idea was to implement it as a workbench that integrates and controls mesh generation and simulation software. At the same time, CAESES needs to provide a fully parametric 3D blade design that allows Caterpillar Propulsion's engineers to reconstruct the definitions of existing blades and profiles, while also requiring high flexibility to try out entirely new designs. *For more details, please refer to the related link. For further information, you can download the PDF or feel free to contact us.*

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  • Mechanical Design

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