Rocky is designed to solve engineering problems. Rocky is uniquely capable to models real particle shapes including any solids, 2D shells, and rigid and flexible fibers. The simulations are fast and accurate. With multi-graphics processing unit (GPU) solver technology, you can simulate the behavior of different shaped and sized particles in many industrial applications.
Using DEM to design a more robust heat exchanger
Compared to bench-top component-level testing, overall foulant simulation can produce savings of up to 10% of total development costs — along with reduced time to market, since results are available in a week, compared to months.
Built-in appliances fill today’s high-end kitchens, in which seamless integration with cabinetry can pose technical challenges related to airflow restriction in a machine’s compartment. This problem is exacerbated by dirt accumulation on the condenser (heat exchanger), which can affect appliance performance.
Experimental evaluation of dirt accumulation on condensers is time-consuming and expensive. Consequently, Sub-Zero is coupling Ansys Fluent computational fluid dynamics (CFD) and Ansys Rocky discrete element modeling (DEM) to quickly gain insight on the mechanisms behind dirt accumulation in an effort to design a more robust heat exchanger.
Ansys Rocky fosters particle mechanics simulation beyond traditional DEM. In 2023 R2, new SPH (Smoothed-Particle Hydrodynamics) capabilities, improved GPU algorithms, and multiphysics take your engineering simulations to the next level.
Elevate your information extraction to a new level by unlocking the power of new cutting-edge post-processing capabilities, featuring streamlines, flow tracers, and innovative boundary interaction statistics such as wet time and heat transfer.
Improved GPU algorithms empower you to effortlessly handle massive STL files and take on much larger geometries with the Rocky solver. Plus, enhanced partitioning algorithm boosts performance for multi-GPU cases, allowing you to run big cases with unparalleled ease.
Unleash the full potential of multiphysics coupling and solve complex problems like never before. Furthermore, there are new modules, such as the particle reorientation triggered by a magnetic field and the drag force induced by a secondary fluid phase tailored for SPH-DEM simulations.
Ansys Rocky unlocks the potential of solving the most challenging DEM simulations. Large scale simulations, going up to millions of particles, can be solved using real particle shapes on multi GPU’s.
Rocky is the premier tool for quickly and accurately simulating the behavior of bulk materials with complex particle shapes and size distributions.
The multi-GPU solver in Rocky distributes and manages the combined memory of two or more GPU cards within a single motherboard, overcoming memory limitations and achieving a substantial performance increase by aggregating computing power. Rocky can speed up your particle simulations and help facilitate large-scale simulations involving tens of millions of particles.
Rocky enables you to simulate a system with real particle shapes and sizes, specifying both spherical and truly non-spherical particle shapes, including shells and fibers. You can set up particle groups with particle size distributions and mix simulations of different particle shapes. Rocky comes with default shapes that you can use out-of-the-box or modify to match your particles. You can also define and import your own custom shapes. Fiber particles in Rocky can be of any length, flexible or rigid, and can be breakable.
Engineers need to assess to interaction of fluid and particles in many applications. Rocky coupled with Ansys Fluent creates a powerful workflow for modeling fluid systems. Specially for non-spherical particles or for systems with particle size distribution, engineers can create a multiphysics simulation by coupling CFD and DEM. CFD-DEM coupling can be used in two different ways:
Coupling DEM with FEA, engineers can simulate transient cases while incorporating geometry motion and time-varying loads on boundary elements.
During simulation, Rocky tracks the loads on each node of a geometry mesh. These loads are then exported as a pressure field for further analysis with Ansys Mechanical. The FEA software then discretizes the geometry and solves for the equilibrium conditions.
Rocky enables solutions of particle flow affected by electromagnetic fields by coupling with Ansys Maxwell. Electric particles can experience three types of phenomena, with particles being influenced by electromagnetic fields, electrostatic fields or tribocharging. The magnetic fields calculated by EM solvers are imported as point clouds into Rocky. The resulting calculations show the particle flow, including particle attraction depending on the charge.
Rocky gives you the freedom to configure complex geometry movements by enabling as many translational, rotational, vibrational, swinging, crushing and free-body motions as you need. The fully integrated motion kernel offers support for combined geometry motions within the software.
Whether you want to prescribe exact movements or have your geometry components move freely in response to outside forces like particle contacts and gravity, Rocky has your complex motion needs covered. For more complex motions with that combine the effects of loads and mechanics, Rocky can be coupled to Ansys Motion.
Rocky’s unique, discrete breakage model is a high-fidelity model that considers the collision location at the particle’s surface along with its consequent internal stresses, capturing shape-dependent breakage and crack propagation.
Unlike most DEM codes that use a combination of spheres connected to each other to approximate a particle shape, Rocky uses tetrahedra, allowing for representation of any particle shape while preserving volume and mass. Thus, it can simulate breakage for particles of any shape and aspect ratio: fibers, shells and custom-shaped particles.
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