December 4, 2024
Yasser Amini

Yasser Amini

Academic Rank: Associate professor
Address:
Degree: Ph.D in Mechanical Engineering
Phone: 07731222171
Faculty: Faculty of Engineering

Research

Title
Numerical simulation of nanofluid flow and heat transfer from a porous cylinder using the mixture multiphase model
Type Thesis
Keywords
محيط متخلخل، نانوسيال، تعادل حرارتي موضعي، عدم تعادل حرارتي موضعي، روش دوفازي مخلوط، روش تكفازي همگن
Researchers shohreh Heydari (Student) , Yasser Amini (Primary advisor) , Marzie Babaie Rabiee (Advisor)

Abstract

Today, a large part of the energy required in industry and also for domestic use is in the form of thermal energy. For this reason, researchers have always sought to improve or develop new ways to increase the rate of heat transfer in thermal systems. As a result of these efforts, their efficiency has increased and economic costs have decreased in most cases. In recent years, viscous fluid flow and forced convection heat transfer from the cylinder has been the focus of many researchers due to its wide application in heat exchangers. Many methods are used to improve the performance of these devices, leading to energy savings, reduction of system size and heat transfer time. Among these methods, we can mention the use of nanofluids and porous materials, which are passive methods of increasing heat transfer. In this regard, this thesis first numerically investigates the flow of nanofluid and heat transfer around and inside a full porous cylinder and a cylinder with a porous coating, taking into account the relative velocity between the base fluid and the nanoparticle and the equality of the temperature of the solid phase and the nanofluid of the porous medium using Fluent software pays. For this purpose, mixture two-phase method for nanofluid modeling and Darcy-BrinkmanForchheimer model and one-equation energy model have been used for modeling flow and heat in porous media. In the second part of the thesis, the hydrodynamic and thermal investigation of the cross-flow of nanofluid from a cylinder with a porous coating, assuming no slippage of the base fluid and nanoparticle, and the temperature inequality of the solid phase and the nanofluid of the porous medium, has been discussed using Comsol software. The results showed that the increase of Darcy number, Reynolds number and volume fraction increases the heat transfer from the porous cylinder and the effect of Darcy number on heat increase is greater than that of volume fraction. Increasing the Reynolds number and the