THE EFFECT OF OPERATING CONDITIONS AND FURNACE GEOMETRY ON THE ATTAINMENT OF FLOW CONDITIONS OF THE FLOATING RICE HUSK PARTICLE

THE EFFECT OF OPERATING CONDITIONS AND FURNACE GEOMETRY ON THE ATTAINMENT OF FLOW CONDITIONS OF THE FLOATING RICE HUSK PARTICLE

furnace. The combustion chamber used needs to be designed in such a way as to obtain the desired particle flow conditions. This study aims to see the effect of geometry and operating conditions of the combustion chamber on the achievement of rice husk particle flow conditions in the combustion chamb...

Full description

Saved in:
Bibliographic Details
Main Author: Novebriantika
Format: Theses
Language:Indonesia
Subjects:
Teknik kimia
Online Access:https://digilib.itb.ac.id/gdl/view/60609
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: Institut Teknologi Bandung
Language: Indonesia
id id-itb.:60609
spelling id-itb.:606092021-09-20T08:30:58ZTHE EFFECT OF OPERATING CONDITIONS AND FURNACE GEOMETRY ON THE ATTAINMENT OF FLOW CONDITIONS OF THE FLOATING RICE HUSK PARTICLE Novebriantika Teknik kimia Indonesia Theses rice husk, combustion chamber, CFD, RANS, turbulent RSM INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/60609 furnace. The combustion chamber used needs to be designed in such a way as to obtain the desired particle flow conditions. This study aims to see the effect of geometry and operating conditions of the combustion chamber on the achievement of rice husk particle flow conditions in the combustion chamber. Particle flow conditions are simulated using the Computational Fluid Dynamic (CFD) tool and the device used is the ANSYS Fluent student version. Variations are made on the shape of the combustion chamber (box and cylinder), the size of the combustion chamber, and the number of secondary inlets. The operating conditions were carried out by varying the amount of excess air (EA) and particle diameter. The fluid dynamics modeling in this study uses the mass conservation equation and turbulent momentum which is also known as the Reynolds Average Navier-Stokes (RANS) equation. Meanwhile, the model used to solve the system of equations is the RSM turbulent model. The simulation results show that the magnitude velocity increases with the increase in the amount of excess air, but will decrease with the increasing size of the combustion chamber and the increase in the number of secondary air inlets. Increasing the number of secondary air inlets and the larger the size of the combustion chamber will reduce the intensity of the turbulence that occurs, while increasing the amount of excess air will increase the intensity of the turbulence. The residence time of the particles will decrease with the increase in the amount of excess air, and the size of the combustion chamber, but will increase with the increase in the number of secondary air inlets and the size of the particle diameter. Cylindrical geometry has higher magnitude velocity, turbulent intensity, residence time, and static pressure when compared to box geometry. The cylinder geometry combustion chamber is superior to the box geometry combustion chamber, because it has better turbulence intensity, residence time, and flow structure. text
institution Institut Teknologi Bandung
building Institut Teknologi Bandung Library
continent Asia
country Indonesia
Indonesia
content_provider Institut Teknologi Bandung
collection Digital ITB
language Indonesia
topic Teknik kimia
spellingShingle Teknik kimia
Novebriantika
THE EFFECT OF OPERATING CONDITIONS AND FURNACE GEOMETRY ON THE ATTAINMENT OF FLOW CONDITIONS OF THE FLOATING RICE HUSK PARTICLE
description furnace. The combustion chamber used needs to be designed in such a way as to obtain the desired particle flow conditions. This study aims to see the effect of geometry and operating conditions of the combustion chamber on the achievement of rice husk particle flow conditions in the combustion chamber. Particle flow conditions are simulated using the Computational Fluid Dynamic (CFD) tool and the device used is the ANSYS Fluent student version. Variations are made on the shape of the combustion chamber (box and cylinder), the size of the combustion chamber, and the number of secondary inlets. The operating conditions were carried out by varying the amount of excess air (EA) and particle diameter. The fluid dynamics modeling in this study uses the mass conservation equation and turbulent momentum which is also known as the Reynolds Average Navier-Stokes (RANS) equation. Meanwhile, the model used to solve the system of equations is the RSM turbulent model. The simulation results show that the magnitude velocity increases with the increase in the amount of excess air, but will decrease with the increasing size of the combustion chamber and the increase in the number of secondary air inlets. Increasing the number of secondary air inlets and the larger the size of the combustion chamber will reduce the intensity of the turbulence that occurs, while increasing the amount of excess air will increase the intensity of the turbulence. The residence time of the particles will decrease with the increase in the amount of excess air, and the size of the combustion chamber, but will increase with the increase in the number of secondary air inlets and the size of the particle diameter. Cylindrical geometry has higher magnitude velocity, turbulent intensity, residence time, and static pressure when compared to box geometry. The cylinder geometry combustion chamber is superior to the box geometry combustion chamber, because it has better turbulence intensity, residence time, and flow structure.
format Theses
author Novebriantika
author_facet Novebriantika
author_sort Novebriantika
title THE EFFECT OF OPERATING CONDITIONS AND FURNACE GEOMETRY ON THE ATTAINMENT OF FLOW CONDITIONS OF THE FLOATING RICE HUSK PARTICLE
title_short THE EFFECT OF OPERATING CONDITIONS AND FURNACE GEOMETRY ON THE ATTAINMENT OF FLOW CONDITIONS OF THE FLOATING RICE HUSK PARTICLE
title_full THE EFFECT OF OPERATING CONDITIONS AND FURNACE GEOMETRY ON THE ATTAINMENT OF FLOW CONDITIONS OF THE FLOATING RICE HUSK PARTICLE
title_fullStr THE EFFECT OF OPERATING CONDITIONS AND FURNACE GEOMETRY ON THE ATTAINMENT OF FLOW CONDITIONS OF THE FLOATING RICE HUSK PARTICLE
title_full_unstemmed THE EFFECT OF OPERATING CONDITIONS AND FURNACE GEOMETRY ON THE ATTAINMENT OF FLOW CONDITIONS OF THE FLOATING RICE HUSK PARTICLE
title_sort effect of operating conditions and furnace geometry on the attainment of flow conditions of the floating rice husk particle
url https://digilib.itb.ac.id/gdl/view/60609
_version_ 1822931420256927744

Similar Items