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Simulation Software(Test) - 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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CFD optimization through integration with AnsysCFD.

CFD optimization through integration with AnsysCFD.

An appropriate CAD tool is needed to ensure the generation of various model variations to be analyzed in the automation process!

Ansys CFD tools such as Fluent and CFX receive strong support from engineers for evaluating fluid dynamic behavior in design, along with various options and tools used for mesh creation. These tools provide valuable information and insights regarding the performance to be evaluated. Moreover, they enable automated optimization and design exploration workflows that include CFD. In addition to improving design and shortening development time and design cycles, these tools significantly enhance the development process by increasing information about the impact of various design variables on performance (product behavior) during the initial design phase, where there is a high degree of freedom in decision-making. *For more details, you can view the related links. For more information, please download the PDF or feel free to contact us.*

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  • Structural Analysis
  • Other CAD

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Propeller optimization using machine learning

Propeller optimization using machine learning

The main objective of the contest was to design a propeller that could achieve maximum efficiency at a wide range of operating speeds.

In propeller design, achieving optimal efficiency and performance is extremely important. Recently, by effectively combining AI and CFD, we were able to win an online propeller design contest hosted by a popular YouTube creator. In this contest, we were able to create two high-performance propellers that demonstrated excellent efficiency using "CAESES" and "AirShaper." *For more details, you can view the related links. For more information, please download the PDF or feel free to contact us.*

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  • Image analysis software
  • Structural Analysis

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Optimization of bulk carrier shape

Optimization of bulk carrier shape

The objective function of the first stage of optimization was set for five combinations of draft and speed regarding power consumption and hull weight at sea.

This time, we will introduce a case of optimization for bulk carriers by DNV GL, a European classification society. This case involves the optimization calculations for the hull and propeller of a bulk carrier. The hull in question is an Ultramax-sized hull called "Diamond 2." The optimization includes wave reduction, propulsion at the stern, twisting at the stern, and propeller design, with the shapes created using the CAD features of CAESES. *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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Parametric modeling of turbine blade cooling structures

Parametric modeling of turbine blade cooling structures

Introduction to CAESES parametric modeling of blades with cooling structures for optimization!

In gas turbines and steam turbines, the design and optimization of blade cooling structures is a very important issue for designers. The first stage of the turbine can achieve high thermal efficiency as it withstands high temperatures, which opens up infinite possibilities for structural design and fine-tuning to prevent turbine damage under high temperatures and high centrifugal forces. One efficient method to solve this design problem is shape optimization, which involves automatically varying the design parameters of the cooling structure. *For more detailed information, please refer to the related link. For further details, you can download the PDF or feel free to contact us.*

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  • Structural Analysis
  • Turbine

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A New Approach to the Design of sCO2 Axial Flow Turbines

A New Approach to the Design of sCO2 Axial Flow Turbines

Introducing a design case of a supercritical carbon dioxide axial flow turbine for waste heat recovery (WHR) in a 10MW class power plant!

In conventional thermal and nuclear power plants, steam and combustion gases are used as working fluids to drive turbines and generate electricity. In this case, we will introduce a design method for axial flow turbines using supercritical carbon dioxide (sCO2) as the working fluid, which reaches a supercritical state under relatively mild conditions using CAESES. The supercritical state exhibits properties that are intermediate between gas and liquid, and due to its high density and heat capacity, it has the potential to improve cycle efficiency compared to using gases below the critical point. *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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  • Turbine

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Optimization of the air intake for AIPOD.

Optimization of the air intake for AIPOD.

Introduction to parametric modeling using CAD and optimization software CAESES.

This article introduces the air intake optimization of ramjet engines using AIPOD, our self-developed optimization platform. Ramjet engines are designed for air intake at Mach numbers of 3 and above, where the mixture flows in and the exit becomes subsonic, making it a type of jet engine. To accommodate different flight Mach numbers, a center cone called a spike can be moved forward and backward, and when the maximum flight Mach number of 3.5 is reached, the Mach line formed at the tapered vertex intersects exactly with the lip. *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

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Design and Optimization of VOITH Linear Jet

Design and Optimization of VOITH Linear Jet

Maintains high efficiency across the entire speed range of the vessel. Reduces cavitation, noise, and vibration.

The VOITH company's linear jet design, which is a challenging ship system characterized by complex shape features, combinations of multiple parts, and large-scale CFD calculation models, provides high customer satisfaction products by establishing and operating a fully automated design system using CAESES. The VOITH Linear Jet (VLJ) combines the simplicity of a propeller with the high-speed performance of a water jet. One of the most important challenges in the design of this product is to delay the occurrence of cavitation while maintaining high efficiency over a wide operating range. *For more detailed information, please refer to the related links. For more 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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Acquisition of design parameters for geometry based on neural networks.

Acquisition of design parameters for geometry based on neural networks.

A method devised to understand design parameters from geometry for ship shape optimization!

In parametric modeling using CAESES, shape control is performed using the created model and the functions that serve as design parameters. However, there may be situations where the values of the design parameters are unknown, and there may be cases where one wishes to obtain design parameters from an already created model. The case introduced here is part of a project undertaken by a graduate student at Hamburg University of Technology. The method devised to determine design parameters from geometry for ship shape optimization is expected to be applicable in many other applications as well. *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

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Parametric model of end wall contouring

Parametric model of end wall contouring

We will also introduce modeling approaches, the construction of more complex models, and application examples!

In the end wall section of power generation devices that convert the kinetic energy of fluids, such as turbines and compressors, into rotational motion, a secondary flow known as "cross flow" occurs due to the interaction between adjacent blades. To improve the performance of the device, it is crucial to reduce this cross flow and the resulting flow losses. The end wall contouring introduced here is a shape profile that adds irregularities to the end wall to suppress losses caused by cross flow, and it is modeled parametrically using CAESES. With the addition of these shape features and modeling techniques, it has become possible to modify the hub shape, thereby minimizing undesirable secondary flow losses. *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

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Tire tread pattern optimization

Tire tread pattern optimization

A system for automatic optimization has been built using CAESES and commercial CFD analysis tools, resulting in significant improvements to the tire tread pattern!

The development of advanced automotive systems such as electric vehicles, autonomous driving systems, and safety enhancement systems will significantly increase the number of electronic devices added to the vehicle body, including sensors, radars, and cameras. It is crucial for these devices to function reliably while minimizing exposure to water to prevent damage and corrosion. One effective approach to achieve this is to reduce water splashes on the vehicle's body and underbody. This case study introduces simulation-driven optimization to investigate the impact of tire tread patterns on water splashes. *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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  • Other analysis software

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Optimization of thermal design for electric vehicle battery packs

Optimization of thermal design for electric vehicle battery packs

The parametric model created with CAESES can robustly output various complex shapes for use in optimization calculations!

The battery is one of the most important components in electric vehicles (EVs), and its performance and lifespan have a significant impact on the vehicle's driving range, safety, and even energy efficiency. In particular, the operating temperature of the battery is directly related to the charging and discharging efficiency and degradation rate, making proper temperature management essential. If the temperature is not adequately controlled, issues such as accelerated degradation due to overheating, reduced safety, or, conversely, decreased output and charging efficiency in low-temperature environments may arise. Therefore, the thermal design of the battery pack is a crucial factor in maximizing the performance of EVs and ensuring long-term durability. In this case study, we constructed a parametric battery model with flexible deformation and conducted optimization calculations aimed at minimizing the maximum temperature. *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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Simulation tire model "FTire"

Simulation tire model "FTire"

Reflecting more realistic tire behavior in model-based development!

This is a three-dimensional tire model that enables simulation evaluations of durability and ride comfort using a high-frequency short-wavelength nonlinear tire model by calculating the number of contacts between the road surface and the tire at 200 points. In recent years, there has been an increasing demand for driving simulators where the feeling, such as ride comfort, is important, and it also supports real-time applications. Case 1: Riding over a curb... Due to the 200-point multi-contact, it is possible to obtain results similar to actual behavior. Case 2: Vibration on uneven surfaces... It is possible to verify ride comfort considering the deformation of the tire rubber. Case 3: Low-speed steering behavior... It is possible to reproduce tire behavior at low speeds. Evaluation licenses are also available, so if you are interested, please contact us at the link below. https://www.neorium.co.jp/contact-us/

  • simulator

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[Case Study] Combustion Analysis of Corn Burners 'AICFD'

[Case Study] Combustion Analysis of Corn Burners 'AICFD'

Efficiently solving complex flow and heat transfer problems! Case study of combustion analysis of a conical burner.

We would like to introduce a combustion analysis case of a conical burner using the general-purpose thermal fluid analysis software "AICFD." The analysis conditions include a turbulence model of the standard k-ε model, a fluid mixture, and a combustion model such as Species Transport. This product comprehensively covers the process from creating the analysis model, simulation, to result processing, supporting the improvement of research and development efficiency. 【Analysis Conditions (Partial)】 ■ Inlet Conditions: - 60 [m/s] - CH4 (mass percent: 3.4%) - O2 (mass percent: 22.5%) - N2 (mass percent: 74.1%) *For more details, please download the PDF or feel free to contact us.

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  • Other analysis software

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Plant Digital X Corporation

Plant Digital X Corporation

We will propose and provide AVEVA solutions that match your company's needs.

As an AVEVA solution provider, we offer engineering services utilizing AVEVA Process Simulation (APS) by a team centered around plant engineers. By leveraging APS, we support our customers in various aspects of production activities, from research and development to maintenance. We solve various challenges that could not be addressed by conventional process simulators.

  • simulator

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