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Heat Exchanger Training Package, Advanced CFD User

$870.00 Student Discount

  • Shell and Tube Heat Exchanger
  • Triplex Tube Heat Exchanger
  • Finned Tube Heat Exchanger
  • Double Pipe Heat Exchanger
  • Porous Heat Exchanger
  • Solar Heat Exchanger
  • Plate Heat Exchanger

 



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 +1 (903) 231-3943.

There are some Free Products to check our service quality.

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

Nano Fluid Heat Transfer in a Porous Heat Exchanger, ANSYS Fluent Tutorial

  • The problem numerically simulates Nano Fluid Heat Transfer in a Porous Heat Exchanger 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 4148881.
  • The Energy Equation is activated to consider heat transfer.

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.

Solar Heat Exchanger, ANSYS Fluent CFD Simulation Tutorial

  • The problem numerically simulates the Solar Heat Exchanger 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 304200.
  • We use Discrete Ordinates (DO) and Solar Ray Tracing to consider radiation heat transfer.

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.

Conjugated Heat Transfer, Elliptical Finned Tube Heat Exchanger Vs. Circular Fin

In this project, by investigating conjugated heat transfer, the effect of cross-sectional change (with the constant area) on the rate of improvement of heat flux passing through the circular and elliptical finned tube heat exchanger was compared.

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.

Heat Recovery, Counter and Cross Flow Plate Heat Exchangers, Paper Numerical Validation

  • The problem numerically simulates a cross-flow heat exchanger plate panel using ANSYS Fluent software.
  • We design the 2-D model with the Design Modeler software.
  • We Mesh the model with ANSYS Meshing software.
  • The mesh type is Structured, and the element number equals 155000.
  • This project is simulated and validated with a reference article.

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.

Nanofluid Heat transfer in Double Pipe Heat Exchanger, Paper Numerical Validation

The present problem validates the article "Heat transfer enhancement of nanofluids in a double pipe heat exchanger with louvered strip inserts" applying CFD simulation, using ANSYS Fluent software.

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.

Thermal Storage by PCM in a Triplex Tube Heat Exchanger, Paper Numerical Validation

The present problem simulates heat transfer in a triplex tube heat exchanger containing phase change material (PCM) using ANSYS Fluent software. This simulation is based on the information of a reference article "Internal and external fin heat transfer enhancement technique for latent heat thermal energy storage in triplex tube heat exchangers" and its results are compared and validated with the results in the article.

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.

Sedimentation and Erosion in a Shell and Tube, Ansys Fluent CFD Simulation Training

  • The problem numerically simulates Sedimentation and Erosion in a Shell and Tube Heat Exchanger 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 640618.
  • We perform this simulation as unsteady (Transient).
  • We use Discrete Phase Model (DPM) to define Sand Injection inside the heat exchanger.
  • We aim to predict the Erosion Effect by different methods: Finnie, Oka, and Mclaury.

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.

Shell and Tube Heat Exchanger, PCM Thermal Storage System, Paper Numerical Validation

  • The problem numerically simulates the shell and tube heat exchanger as a PCM thermal storage system using 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 169171.
  • We define the Solidification and Melting model to define phase change material.
  • We use a UDF to define the temperature-dependent viscosity.
  • This simulation is validated with a reference article.

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.

shell and tube heat exchanger with staggered baffles, Paper Numerical Validation

  • The problem numerically simulates the shell and tube heat exchanger with staggered baffles using 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 8031342.
  • This simulation is validated with a reference article.

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.

Shell and Tube Heat Exchanger Numerical Study, Industrial Application

In this project, an industrial Shell and Tube has been simulated and the results of this simulation have been investigated.

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.

If you need the Geometry designing and Mesh generation training video for all the products, you can choose this option.

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.

Description

Heat Exchanger Training Package, 10 CFD Projects for Advanced Users

In this heat exchanger training package, we will study different kinds of Heat Exchangers. First, start with Shell and Tube type as one of the most popular heat exchangers. An authentic industrial with a bunch of tubes will be studied, then the effect of staggered baffles, PCM thermal storage system, and sedimentation and erosion will be simulated and also validated with related credit papers.

The other kinds of heat exchangers are included in this training package such as triplex tubes (thermal storage by PCM), finned tubes (comparing conjugated heat transfer with elliptical and circular fins), double pipe, and porous heat exchangers (nano-fluid heat transfer).

The last analysis dedicates the plate heat exchanger (heat recovery comparison with counter and cross flows) and solar heat exchanger as two of the most important type.

 

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