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UDF for Advance Application: ANSYS Fluent Training Package, 5 CFD Simulations

Original price was: $1,230.00.Current price is: $449.00. Student Discount

  • Master advanced UDF applications for EHD, MHD, PBM, and drag modeling in ANSYS Fluent.
  • Learn to simulate magnetic effects on nanofluid heat transfer and particle separation.
  • Apply population balance models for nucleation and growth simulations.
  • Use UDFs to model drag forces between particles and fluid interactions.
  • Explore Prandtl number modeling with macro UDFs for enhanced heat transfer analysis.
  • Gain hands-on expertise with five diverse CFD simulations for advanced engineering
Click on Add To Cart and obtain the Geometry file, Mesh file, and a Comprehensive ANSYS Fluent Training Video.

To Order Your Project or benefit from a CFD consultation, contact our experts via email ([email protected]), online support tab, or WhatsApp at +44 7443 197273.

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If you want the training video in another language instead of English, ask it via [email protected] after you buy the product.

Magnetic Field Effect on Nanofluid Heat Transfer (MHD)

In this project, nanofluid flows in a solid aluminum channel in the presence of an applied magnetic field.

Spiral Magnetic Separator CFD Simulation

  • This study investigates the performance of a spiral magnetic separator using ANSYS Fluent.
  • The geometry, representing a spiral-shaped separator with multiple turns, is designed in ANSYS SpaceClaim and meshed using ANSYS Meshing.
  • The simulation is conducted as a steady-state analysis with a pressure-based solver.
  • The Realizable k-epsilon turbulence model is employed, along with a two-way coupled Discrete Phase Model (DPM) for particle simulation.
  • The Magnetic Induction MHD Method is enabled to model the applied magnetic field, with User-Defined Functions (UDFs) implemented for magnetic field components.
  • Results reveal complex interactions between fluid flow, magnetic particles, and the applied magnetic field, demonstrating the separator’s effectiveness in particle segregation.

Population Balance Model for Nucleation, PBM Tutorial

  • The problem numerically simulates Population Balance Model (PBM) for Nucleation using ANSYS Fluent software.
  • We design the 3-D model by the Design Modeler software.
  • We Mesh the model by ANSYS Meshing software, and the element number equals 112077.
  • We use the Species Transport model to define a mixture of water, calcium, and oxalate as the initial phase.
  • We use the Eulerian Multiphase model to define a two-phase flow, in which the secondary phase is calcium-oxalate, resulting from a chemical reaction.
  • We use The population balance model (PBM) to study produced particles' behavior and predict the density or population of particles in specific sizes.
  • We use a UDF function to define the nucleation and growth rates in PBM analysis.

DPM-Drag Macro, UDF, Drag between Particles and Fluid CFD Simulation

  • The problem numerically simulates the particle spraying in continuous fluid ANSYS Fluent software.
  • We design the 3-D model with the Design Modeler software.
  • We mesh the model with ANSYS Meshing software, and the element number equals 127,100.
  • We performed the simulation in Transient (unsteady-state).
  • We use the Discrete Phase Model (DPM) to define particle spraying.
  • We use the User-Defined Function (UDF) to define a drag between particles and fluid.
  • We use the DPM-DRAG Macro for UDF.
  • We compare different Drga Laws, including Spherical, Stokes Cunningham, Non-spherical, and High-Mach.

Prandtl-K Macro, UDF, Prandtl number CFD Simulation

  • The problem numerically simulates the turbulence model using ANSYS Fluent software.
  • We design the 2-D model with the Design Modeler software.
  • We mesh the model with ANSYS Meshing software, and the element number equals 97,972.
  • We use the User-Defined Function (UDF) to define the Prandtl number.
  • We use the Prandtl_K Macro for UDF.

Special Offers For All Products

If you need the Geometry designing and Mesh generation training video for all the products, you can choose this option.
The journal file in ANSYS Fluent is used to record and automate simulations for repeatability and batch processing.
Editable geometry and mesh allows users to create and modify geometry and mesh to define the computational domain for simulations.
The case and data files in ANSYS Fluent store the simulation setup and results, respectively, for analysis and post-processing.
Geometry, Mesh, and CFD Simulation methodologygy explanation, result analysis and conclusion
If you want training in any language other than English, we can provide you with a subtitled video in your language.

Special Offers For Single Product

If you need the Geometry designing and Mesh generation training video for one product, you can choose this option.
If you need expert consultation through the training video, this option gives you 1-hour technical support.
The journal file in ANSYS Fluent is used to record and automate simulations for repeatability and batch processing.
editable geometry and mesh allows users to create and modify geometry and mesh to define the computational domain for simulations.
The case and data files in ANSYS Fluent store the simulation setup and results, respectively, for analysis and post-processing.
Geometry, Mesh, and CFD Simulation methodologygy explanation, result analysis and conclusion
The MR CFD certification can be a valuable addition to a student resume, and passing the interactive test can demonstrate a strong understanding of CFD simulation principles and techniques related to this product.
Enhancing Your Project: Comprehensive Consultation and Optimization Services
Collaborative Development of a Conference Paper on Cutting-Edge Topics with MR CFD
Collaborative Publication Opportunity: Contribute to an ISI Article and Get Featured in Scopus and JCR-Indexed Journals
If you want training in any language other than English, we can provide you with a subtitled video in your language.

Description

UDF Application for Advance Application (EHD/MDH; PBM (Nucleation and Growth); Drag between Particles; & Prandtl Number) modeling by ANSYS Fluent

Introduction: Advanced UDF Applications in ANSYS Fluent

This training package explores the advanced use of User-Defined Functions (UDFs) in ANSYS Fluent for modeling complex engineering phenomena. Topics include Electrohydrodynamics (EHD), Magnetohydrodynamics (MHD), Population Balance Models (PBM), particle-fluid drag interactions, and Prandtl number effects. Through five detailed simulations, participants will gain practical skills in customizing and solving advanced CFD problems across multiple industries.

Magnetic Field Effect on Nanofluid Heat Transfer (MHD)

Begin by exploring the effects of magnetic fields on nanofluid heat transfer in MHD systems. This simulation highlights how magnetic forces influence flow and thermal properties, enabling learners to design efficient cooling systems and enhance heat transfer performance.

Population Balance Model for Nucleation and Growth

Delve into Population Balance Modeling (PBM) to simulate nucleation and growth processes in fluid systems. This session focuses on applying PBM to predict particle size distribution, making it valuable for industries like chemical processing and crystallization.

DPM-Drag Macro UDF: Drag between Particles and Fluid

This simulation focuses on the Discrete Phase Model (DPM) and UDFs to model drag forces between particles and the fluid. Participants will learn to implement macros to customize drag interactions, which are crucial for accurately modeling multiphase flows and particulate systems.

Spiral Magnetic Separator CFD Simulation

Simulate the operation of a spiral magnetic separator to understand particle separation under the influence of a magnetic field. This case study combines MHD principles with CFD to optimize separation efficiency in industrial processes.

Prandtl-K Macro UDF: Prandtl Number Modeling

Explore heat transfer enhancement through Prandtl number modeling. This simulation demonstrates the use of macro UDFs to control Prandtl number variations dynamically, providing insights into fluid flow and thermal conductivity.

Conclusion: Mastering Advanced UDF Applications

The course concludes by summarizing the key concepts and simulations. By mastering UDFs for EHD, MHD, PBM, drag modeling, and Prandtl number, participants will be equipped to address cutting-edge engineering challenges in industries such as energy, chemical processing, and advanced manufacturing.

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