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radiation

Radiation Model Training Course

$480.00 Student Discount

Chapter 1: (Radiation Model Concepts): Introduction and overview of Radiation model fundamentals

Chapter 2: (Training Example 1): P1 Radiation Model, Gasification in Gasifier Chamber

Chapter 3: (Training Example 2): Rosseland Radiation Model, Combustion of Train in Tunnel

Chapter 4: (Training Example 3): DTRM Radiation Model, Atrium Natural Ventilation

Chapter 5: (Training Example 4): S2S Radiation Model, Radiative Space Heater

Chapter 6: (Training Example 5): Discrete Ordinates Radiation Model, Solar Radiation at Different Hours

Chapter 7: (Training Example 6): Monte Carlo Radiation, CT Scan

Click on Add To Cart and obtain the Geometry file, Mesh file, and a Comprehensive ANSYS Fluent Training Video. By the way, You can pay in installments through Klarna, Afterpay (Clearpay), and Affirm.

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.
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radiation

Radiation Model Concepts in ANSYS Fluent

  • Introduction to Radiation Heat Transfer Concepts
  • Introduction to Radiative Transport Equation (RTE)
  • Studying different Radiation Models in ANSYS Fluent
  • Rosseland Radiation Model
  • P1 Radiation Model
  • Surface-to-Surface (S2S) Radiation Model
  • Discrete Ordinates (DO) Radiation Model
  • Discrete Transfer Radiation Model (DTRM)
  • Monte Carlo (MC) Radiation Model
Gasification

Gasification in Gasifier Chamber, P1 Radiation Model

  • The present problem simulates the gasification process inside a gasifier chamber by ANSYS Fluent.
  • The present 3-D model is designed using Design Modeler software. The meshing of the model has been done using ANSYS Meshing software. The element number is 219170.
  • Water vapor is created by the process of evaporation of water droplets inside the chamber by applying DPM.
  • The species transport model with volumetric reactions has been used and to define the type of reactants and the process of chemical reactions. The CHEMKIN mechanism has been used, which includes 5 chemical reactions involving 8 different types of reactants and products.
  • This model also assumes that Radiation heat transfer due to chemical reactions occurs inside the gasifier chamber, and hence, the P1 model is defined for simulation.
Rosseland

Rosseland Radiation Model, Combustion of Train in Tunnel

  • The problem numerically simulates the Combustion of a train in the tunnel 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 372705.
  • We use the Rosseland Radiation Model to define radiation heat transfer.
  • We use Species Transport Model to define combustion reaction.
DTRM

DTRM Radiation Model, Atrium Natural Ventilation

  • The problem numerically simulates Natural Ventilation in Atrium 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 709511.
  • We use the Discrete Transfer Radiation Model (DTRM) to define radiation heat transfer.
  • We use Solar Ray Tracing to apply the effect of solar irradiation.
S2S

S2S Radiation Model, Radiative Space Heater CFD Simulation

  • The problem numerically simulates the Radiative space Heater 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 703545.
  • We use the Surface to Surface Radiation Model (S2S) to define radiation heat transfer.
solar radiation

Solar Radiation at Different Hours, Discrete Ordinates Radiation Model

  • The problem numerically simulates solar radiation at different hours 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 2054294.
  • This study is performed based on the geographical characteristics of Baku (The capital of Azerbaijan) at 8 AM and 3 PM on June 21st.
  • We perform this simulation as unsteady (Transient).
  • We use Discrete Ordinate Radiation (DO) and Solar Ray Tracing to consider radiation heat transfer.
Monte Carlo

Monte Carlo Radiation, CT Scan CFD Simulation

  • The problem numerically simulates Computerized Tomography (CT) Scan 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 4390045.
  • We use the Monte Carlo (MC) Radiation Model to define radiation heat transfer.

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

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.

Description

Radiation Model Training Course

The Radiation Model will teach you how to simulate problems that consider radiation heat transfer. You`ll get acquainted with all the required steps in order to use the Radiation module in ANSYS Fluent.

First of all, we have an overview of the Radiation fundamentals and the required concepts that need to be taken in order to use them in the problems. Next, all the related options related to the Radiation module in ANSYS Fluent software are explained in detail in separate chapters. Finally, we have several practical training examples.

Training Course Syllabus

This course is divided into 7 main chapters. You strongly recommend that you do not skip any of the sections even if you feel you know the content because there all lots of practical points within the explanations.

Chapter 1: Radiation Concepts

In this chapter, we will have a general introduction to the Radiation model and an overview of its application, limitations, pros & cons, and prerequisites. This section contains the following subsections:

  • Introduction and overview of the Radiation Model
  • Introduction to radiation heat transfer
  • Comparison of different Radiation methods with their advantages and limitations
  • Description of Radiation models including Rosseland, P1, DTRM, Discrete Ordinates (DO), Surface to Surface (S2S), and Monte Carlo (MC)
  • Introduction to radiative transport equation (RTE)

Chapter 2: P1 Radiation

In this chapter, we present a practical example of the P1 radiation model. In this project, we simulate the gasification process inside a gasifier chamber using ANSYS Fluent software. During this example, we will explain the radiation model of P1 in detail. We present the formulation and relations of this P1 radiation method and introduce the related parameters. We also talk about the settings of the P1 radiation model in the software environment.

Chapter 3: Rosseland

In this chapter, we present a practical example of the Rosseland radiation model. In this project, we simulate the combustion process in the train’s body inside the tunnel using ANSYS Fluent software. During this example, we will explain the radiation model of Rosseland in detail. We present the formulation and relations of this Rosseland radiation method and introduce the related parameters. We also talk about the settings of the Rosseland radiation model in the software environment.

Chapter 4: Discrete Transfer Radiation Model (DTRM)

In this chapter, we present a practical example of the DTRM radiation model. In this project, we simulate the natural ventilation system process in a three-story atrium building using ANSYS Fluent software. During this example, we will explain the radiation model of DTRM in detail. We present the formulation and relations of this DTRM radiation method and introduce the related parameters. We also talk about the settings of the DTRM radiation model in the software environment.

Chapter 5: Surface to Surface (S2S)

In this chapter, we present a practical example of the S2S radiation model. In this project, we simulate the radiative heat transfer inside a radiative space heater using ANSYS Fluent software. During this example, we will explain the radiation model of S2S in detail. We present the formulation and relations of this S2S radiation method and introduce the related parameters. We also talk about the settings of the S2S radiation model in the software environment.

Chapter 6: Discrete Ordinates (DO)

In this chapter, we present a practical example of the DO radiation model. In this project, we simulate solar radiation at different times using ANSYS Fluent software. During this example, we will explain the radiation model of DO in detail. We present the formulation and relations of this DO radiation method and introduce the related parameters. We also talk about the settings of the DO radiation model in the software environment.

Chapter 7: Monte Carlo (MC)

In this chapter, we present a practical example of the MC radiation model. In this project, we simulate the thermal radiation in a computerized tomography (CT) scan using ANSYS Fluent software. During this example, we will explain the radiation model of MC in detail. We present the formulation and relations of this MC radiation method and introduce the related parameters. We also talk about the settings of the MC radiation model in the software environment.

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