Discover Better Designs, Faster.

Predicting the real-world performance of a product requires simulation tools that span a variety of engineering disciplines. STAR-CCM+ is an all-in-one solution that delivers accurate and efficient multidisciplinary technologies in a single integrated user interface.

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A True Multidisciplinary Platform

Find out how STAR-CCM+ provides for all your simulation needs.


Much more than just a CFD code, STAR-CCM+ is a complete multidisciplinary platform for the simulation of products and designs operating under real-world conditions.

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Fluid Dynamics
The computational fluid dynamics (CFD) capability in STAR-CCM+ offers an efficient and accurate set of fluid dynamics models and solvers with excellent parallel performance and scalability. It provides a solid foundation for multidisciplinary design exploration.
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Heat Transfer
STAR-CCM+ accurately predicts heat transfer in fluids and solids using specialized convection, conduction and radiation models. The automated meshing tools and parts-based simulation option allow you to validate your thermal designs faster.
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STAR-CCM+ offers an extensive library of accurate models for predicting aeroacoustics noise sources, including: steady state models, direct models (DES/LES), propagation models and acoustic perturbation equations (APE) solver.
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Multiphase Flows
Accurately representing the physical behavior of the different fluid and solid phases is key to capturing the real-world performance of your product. STAR-CCM+ offers a variety of both Eulerian and Lagrangian modeling capabilities to suit your simulation needs.
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Particle Flows
The discrete element method (DEM) can be used to simulate the motion of a large number of interacting discrete objects (particles), such as the granular flow of aggregates, food particles, metal powders, tablets and capsules, and wheat or grass. STAR-CCM+ is the first commercial engineering simulation tool to include a DEM capability that is fully coupled with numerical flow simulation.
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Computational rheology is used to model non-Newtonian/viscoelastic materials in industrial problems. The rheology solver in STAR-CCM+ accurately resolves the dominant physics of complex rheological material flow and helps predict their behavior.
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Solid Mechanics
STAR-CCM+ offers both finite volume (FV)-based computational fluid dynamics and finite element (FE)-based computational solid mechanics (CSM) in an easy-to-use single integrated user interface. This allows engineers to expand their simulation scope to include fluid-structure and fluid-thermal-stress interactions.
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Reacting Flows
STAR-CCM+ provides insight into the interactions between turbulent flow field and underlying chemistry of reacting flows, helping you improve the trade-off between the performance and emissions of your device for different operating conditions.
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The electrodynamic, electrostatic and magnetic potential solvers in STAR-CCM+ accurately predict the interactions between electric, magnetic and flow fields, and facilitate successful designs of electric devices and their cooling.
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Significantly improving a battery design across its whole operating range is a challenging task, and involves the simultaneous optimization of numerous parameters. Together with Battery Design Studio, STAR-CCM+ provides a complete simulation environment for the analysis and design of the electrochemical system and detailed geometry of individual battery cells.
In Depth


Don't just simulate, innovate!

In order to design better products, engineers need to predict the consequence of any design changes on the real-world performance of their product, for better or for worse. Historically those predictions came from hand calculations or from the experimental testing of physical prototypes. Today, engineering simulation offers comprehensive predictions that are usually more accurate and always less expensive than experimental testing. Deployed effectively, these can be used to improve a design through multiple iterations. Ultimately this results in higher quality and more robust products that better fulfill customer expectations. Unlike other methods, engineering simulation also offers the benefit of exploring the performance of a product over the full range of operating conditions that it is likely to face in its working life, rather than just at a handful of carefully chosen “design points.” However, not all engineering simulation tools are created equal. In order to provide a constant stream of relevant engineering data, simulation software must be:

Solving complex industrial problems requires simulation tools that span a multitude of physical phenomena and a variety of  engineering disciplines. Real-world engineering problems do not separate themselves into convenient categories such as “aerodynamics”, “hydrodynamics”, “heat transfer” and “solid mechanics”. Only multidisciplinary engineering simulation can accurately capture all of the relevant physics that influence the real-world performance of a product, and can be used to automatically drive the virtual product through a range of design configurations and operating scenarios. By minimizing the level of approximation, engineers can be confident  that the predicted behavior of their design will match the real-world performance of their product.

No matter how “realistic” your simulation is, the data it provides is useless if it does not influence the final design of your product.  For simulation to be a useful tool in the engineering design process, predictions must be delivered on time, every time. A late simulation result is not much better than no result at all.  Ideally, simulation should generate a constant stream of data that guides and informs the design process through every decision. This is only possible when the simulation process is a robust and automated one. Once an engineer has invested in the creation of a multidisciplinary simulation model, that model should be easily redeployable to investigate a full range of design configurations and operating scenarios, with little or no manual effort from the engineer.

Used effectively, engineering simulation consistently delivers a high return on investment (ROI). It provides far more in terms of reduced development costs and increased product revenue than it costs to implement. However, traditional engineering simulation licensing schemes can make the transition from an experimentalist’s mindset of “testing just a few design points” to “investigating the whole design space” prohibitively expensive. This is because most engineering simulation software vendors base their licensing model around the broken paradigm of “the more you use, the more you lose,” charging you per core instead of per simulation and tying customers to an almost linear relationship between the cost of their license and the maximum number of cores that they are allowed to utilize in their simulations. Innovative licensing schemes such as Power Sessions (giving you unlimited cores for a fixed price), Power-on-Demand (enabling you to run on the cloud) and Power Tokens (giving you unprecedented flexibility and facilitating design exploration) render the cost of using engineering simulation affordable.

Backed by experts
An uncomfortable truth about modern engineering is that there really are no easy problems left to solve. In order to meet the demands of industry, it is no longer good enough to do ‘a bit of CFD’ or ‘some stress analysis’.  In order to design truly innovative products, engineers are often “pushing back the boundaries of the possible”. This is something that is difficult to achieve in isolation, and often requires competences  outside an individual engineer’s immediate area of expertise. In order to be successful, an engineer should have ready access to a community of simulation experts, and ideally an established relationship with a dedicated support engineer who not only understands the engineer’s problems, but can approach the right expert help whenever needed.

Case Studies

Designed with STAR-CCM+

See how our customers have been using STAR-CCM+ to generate design improvements and stay ahead of the innovation race.