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STAR-CCM+ Documentation

Simcenter STAR-CCM+ 2406

User Guide

  1. Home
  2. Tutorials

    Tutorials show you how to use Simcenter STAR-CCM+ for various applications in a step-by-step format with recommendations for setup, initialization and steps of the solution process specific to the application. Macro and simulation files are available for download for a large proportion of cases.

  3. Electrochemistry

    The following tutorial demonstrates chemical reactions induced by an electrical current.

  4. Solid Oxide Fuel Cell

    Solid Oxide Fuel Cells (SOFCs) harness the chemical energy that is released by electrochemical reactions and convert it to electrical energy. SOFCs typically consume hydrogen and oxygen and only produce water as a waste product.

  5. Prerequisites

    The instructions in this tutorial assume that you are already familiar with certain techniques in Simcenter STAR-CCM+.

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  • Tutorials

    Tutorials show you how to use Simcenter STAR-CCM+ for various applications in a step-by-step format with recommendations for setup, initialization and steps of the solution process specific to the application. Macro and simulation files are available for download for a large proportion of cases.

    • Using Tutorial Macros and Files

      Macros, input files, and final simulation files for a range of tutorials are provided as an optional download package on the Support Center website. These macros and final simulation files are provided as an aid to the written tutorials, so that you can check your final results against the downloaded files, or against a simulation that is built and run using the macros.

    • Introduction

      Welcome to the Simcenter STAR-CCM+ introductory tutorial. In this tutorial, you explore the important concepts and workflow. Complete this tutorial before attempting any others.

    • Foundation Tutorials

      The foundation tutorials showcase the major features of Simcenter STAR-CCM+ in a series of short tutorials.

    • Geometry

      The tutorials in this set illustrate various Simcenter STAR-CCM+ features for creating and working with parts and 3D-CAD.

    • Mesh

      The tutorials in this set illustrate various STAR-CCM+ features for building CFD meshes.

    • Incompressible Flow

      The tutorials in this set illustrate various Simcenter STAR-CCM+ features for incompressible fluid flows as well as porosity and solution recording

    • Compressible Flow

      The tutorials in this set illustrate various Simcenter STAR-CCM+ features for compressible fluid flows as well as harmonic balance.

    • Heat Transfer and Radiation

      The tutorials in this set illustrate various Simcenter STAR-CCM+ features for heat transfer, radiation, and thermal comfort.

    • Multiphase Flow

      The tutorials in this set illustrate various Simcenter STAR-CCM+ features for simulating multiphase fluid flow problems

    • Discrete Element Method

      The tutorials in this set illustrate various Simcenter STAR-CCM+ features for simulating Discrete Element Method problems

    • Motion

      The tutorials in this set illustrate various STAR-CCM+ features for simulating problems with moving geometries and meshes, dynamic fluid body interaction, and rigid body motion:

    • Reacting Flow

      The tutorials in this set illustrate various Simcenter STAR-CCM+ features for simulating reacting flows such as combustion.

    • Solid Stress

      The tutorials in this set illustrate various Simcenter STAR-CCM+ features for computing deformation, strain, and stresses in solid regions. They also show how such computations can be coupled to the fluid behavior in an analysis of fluid-structure interaction.

    • Aeroacoustics

      The tutorials in this set illustrate various Simcenter STAR-CCM+ features for solving aeroacoustic simulations.

    • Electromagnetism

      The following tutorials illustrate features for solving problems that involve electromagnetic fields.

    • Electrochemistry

      The following tutorial demonstrates chemical reactions induced by an electrical current.

      • Electroplating

        Electroplating is a technique that is commonly used in industry to deposit a metal coating on parts. The part that requires coating sits within an electrolytic solution that contains metal ions. A current is then induced through the electrolyte, between the part acting as the cathode, and an anode that is made of the same metal as the metal ions. In this tutorial, you simulate electroplating of a plastic grille part, which is pre-coated with copper and nickel, using chromium ions.

      • Solid Oxide Fuel Cell

        Solid Oxide Fuel Cells (SOFCs) harness the chemical energy that is released by electrochemical reactions and convert it to electrical energy. SOFCs typically consume hydrogen and oxygen and only produce water as a waste product.

        • Prerequisites

          The instructions in this tutorial assume that you are already familiar with certain techniques in Simcenter STAR-CCM+.

        • Loading an Existing Simulation

          For this tutorial, you use an existing simulation file that contains pre-prepared geometry, a mesh operation that is ready to execute, regions, and interfaces. A selection of field functions are also supplied as a java macro file.

        • Defining Electrochemical Reaction Properties Using Field Functions

          You use custom field functions to define enthalpies, thermodynamic polynomial data, the equilibrium potential, and the equilibrium potential temperature derivative for all reactions within the fluid domains of the fuel cell.

        • Selecting Physics Models

          You define separate solid continua for the anode and cathode current collectors, the solid oxide electrolyte membrane (which separates the anode and cathode), and the tubes. Then you define separate fluid continua for the air and fuel domains.

        • Setting Up the Porous Phases

          You create the anode and cathode porous phases and select the relevant phase models.

        • Setting Material Properties

          For all continua, select material components and adjust material properties.

        • Setting Initial Conditions

          You set the initial temperature, electric potential values, and mole fractions of the fuel and air streams.

        • Defining Surface Reactions

          Electrochemical reactions that occur at the surfaces between the electrodes and the electrolyte are defined manually.

        • Setting Up the Regions and Interfaces

          You specify which continua each of the regions use, and define the properties and values for each region.

        • Generating the Mesh

          Now that the shell region interface is created, you can execute the pre-prepared mesh.

        • Assigning the Surface Reactions

          The cathodic and anodic reactions take place at the cathodic and anodic triple phase boundaries respectively. The triple phase boundaries are represented by interfaces at both sides of the solid oxide electrolyte membrane—between the porous anode and the porous cathode.

        • Setting Up the Boundary and Interface Conditions

          Each region has specific boundary conditions to define.

        • Checking the Conservation of Current, Energy, and Mass

          In this part of the tutorial, you set up reports and generate monitors and plots. These plots check the balance of current, energy, and mass, respectively, throughout the solid oxide fuel cell (SOFC).

        • Vizualizing Concentration and Molar Flux Distribution of Oxygen

          To compare the mole fraction of oxygen alongside the consumption of oxygen on the cathode triple-phase boundary (TPB), you set up a scalar scene for each quantity.

        • Running the Simulation

          For highly diffusive problems like this, increasing the under-relaxation factors of the solvers helps accelerate convergence. With electromagnetic forces being strong forces in their nature, it is important to have well converged simulation results for the electrodynamic potential before converging the other physical quantities like the flow velocities, or species concentrations. In Simcenter STAR-CCM+, convergence can be achieved by using the Presolve feature for the electric potential solver.

        • Analyzing the Results

          When the simulation is complete, review the scenes and plots.

        • Summary

          This tutorial demonstrated electrochemistry for a solid oxide fuel cell.

        • Appendix: User Field Function and Parameters Properties

          Names, dimensions, definitions, and formulation of the user-defined field functions and parameters that are used in the Solid Oxide Fuel Cell tutorial.

        • Bibliography
    • Battery

      The tutorials in this set illustrate various Simcenter STAR-CCM+ features for setting up a battery model:

    • Automation

      The tutorials in this set illustrate various Simcenter STAR-CCM+ automation and macro features.

    • Design Exploration

      The tutorials in this set illustrate various features for running design exploration studies in Design Manager.

    • Coupling with CAE Codes

      The tutorials in this set illustrate various Simcenter STAR-CCM+ features for coupling with CAE codes:

    • Analysis Methods

      The tutorials in this set illustrate various Simcenter STAR-CCM+ features for analysing and visualizing simulation data.

    • Simcenter STAR-CCM+ In-cylinder

      The tutorials in this set illustrate features for simulating internal combustion engines in Simcenter STAR-CCM+ using the dedicated add-on Simcenter STAR-CCM+ In-cylinder.

Prerequisites

The instructions in this tutorial assume that you are already familiar with certain techniques in Simcenter STAR-CCM+.

Technique Tutorial
The Simcenter STAR-CCM+ workflow Introduction to STAR-CCM+
Using visualization tools, scenes, and plots Introduction to STAR-CCM+

If you have not already done so, download the tutorial files bundle. See Downloading the Tutorial Files from the Support Center Portal.

Unpublished work © Siemens 2023

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