The Geometry of a Heat Exchanger (CFD/Flow Simulation)

Table of Contents

• Introduction
• Creation of the Geometry and Mesh
  • Geometry
  • Mesh
• Grid study
  • Grid convergence study
  • Energy Balances
• Investigation of Turbulence Models
  • Comparison of different Turbulence Models
  • Flow Filament Theory
• Final Simulation
  • Most important Flow Values
  • Comparison to Flow Filament Theory
  • Radial Temperature Distribution
  • Specific Cooling Power
• Summary

Objectives and Key Themes

The main objective of this work is to simulate the flow and heat transfer in a heat exchanger using computational fluid dynamics (CFD). The simulation aims to investigate the influence of different turbulence models on the results and to compare these findings with the Flow Filament Theory. The study also focuses on analyzing the radial temperature distribution in the fluid and the specific cooling power of the heat exchanger.

• Application of CFD to simulate fluid flow and heat transfer in a heat exchanger
• Investigation of different turbulence models (e.g., SST, k-omega, EVT)
• Comparison of simulation results with the Flow Filament Theory
• Analysis of the radial temperature distribution in the fluid
• Determination of the specific cooling power of the heat exchanger

Chapter Summaries

• Introduction: This chapter provides a brief overview of the project, introducing the problem and the specific research question. It outlines the objectives of the work and the key themes that will be addressed.
• Creation of the Geometry and Mesh: This chapter details the process of creating the geometry and mesh for the CFD simulation. It explains the specific geometry used, including the dimensions of the heat exchanger, and the different mesh types used (e.g., coarse, medium, fine).
• Grid study: This chapter focuses on the grid convergence study, analyzing the impact of mesh refinement on the simulation results. It investigates how the pressure and temperature distributions are influenced by the mesh size and discusses the criteria used to determine the optimal mesh for the simulation.
• Investigation of Turbulence Models: This chapter explores the effects of using different turbulence models on the simulation results. It compares the performance of various models (e.g., SST, k-omega, EVT) and analyzes their impact on the turbulent kinetic energy, viscosity, and other relevant parameters.
• Final Simulation: This chapter presents the results of the final simulation, using the chosen turbulence model and mesh. It analyzes the flow velocity, pressure, and temperature distributions in both the air and water. The chapter also examines the streamlines, the separation of the air flow, and compares the simulation results with the Flow Filament Theory.

Keywords

The main keywords and focus topics of this work include computational fluid dynamics (CFD), heat exchanger, turbulence models, grid convergence study, Flow Filament Theory, radial temperature distribution, specific cooling power, air flow, water flow, pressure distribution, temperature distribution, simulation analysis, engineering.