Multidisciplinary design of turbine disks

Turbine disks are required to operate at a high temperature environment and rotate at high velocity for good propulsive efficiency of the gas turbine engine. They are constantly subjected to large amount of centrifugal and thermal loads. This combination of loads results in thermomechanical stresses...

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Main Author: Tan, Qi Xiang
Other Authors: Chow Wai Tuck
Format: Final Year Project
Language:English
Published: Nanyang Technological University 2020
Subjects:
Online Access:https://hdl.handle.net/10356/141022
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1410222023-03-04T19:35:49Z Multidisciplinary design of turbine disks Tan, Qi Xiang Chow Wai Tuck School of Mechanical and Aerospace Engineering wtchow@ntu.edu.sg Engineering::Aeronautical engineering Turbine disks are required to operate at a high temperature environment and rotate at high velocity for good propulsive efficiency of the gas turbine engine. They are constantly subjected to large amount of centrifugal and thermal loads. This combination of loads results in thermomechanical stresses, which leads to lower fatigue life of the turbine disk. This report focuses on the study of thermal regulation on turbine disks through new novel designs that will alter the heat transfer coefficients of the disk, and to achieve a reduction in the peak thermal stress encountered by the disk. The design of turbine disks is a multidisciplinary process that includes several disciplines, such as mechanical design, aerodynamics, heat transfer and structural analysis. Analysis of a baseline design shows that the maximum thermal stress experienced by a disk can reach 288.68 MPa. Multiple designs were developed and analysed in this study. Results showed that transient thermal stress level can be reduced by up to 30% in designs where fins were added to the top disk cavity whereas a smaller reduction in stress of up to 1.47% is achieved for designs where fins were added to the bottom disk domain when compared with the existing baseline design. These demonstrated that the effects of heat transfer coefficients on maximum thermal stress are more drastic at the upper region of the disk. Bachelor of Engineering (Aerospace Engineering) 2020-06-03T07:46:48Z 2020-06-03T07:46:48Z 2020 Final Year Project (FYP) https://hdl.handle.net/10356/141022 en A145 application/pdf Nanyang Technological University
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering::Aeronautical engineering
spellingShingle Engineering::Aeronautical engineering
Tan, Qi Xiang
Multidisciplinary design of turbine disks
description Turbine disks are required to operate at a high temperature environment and rotate at high velocity for good propulsive efficiency of the gas turbine engine. They are constantly subjected to large amount of centrifugal and thermal loads. This combination of loads results in thermomechanical stresses, which leads to lower fatigue life of the turbine disk. This report focuses on the study of thermal regulation on turbine disks through new novel designs that will alter the heat transfer coefficients of the disk, and to achieve a reduction in the peak thermal stress encountered by the disk. The design of turbine disks is a multidisciplinary process that includes several disciplines, such as mechanical design, aerodynamics, heat transfer and structural analysis. Analysis of a baseline design shows that the maximum thermal stress experienced by a disk can reach 288.68 MPa. Multiple designs were developed and analysed in this study. Results showed that transient thermal stress level can be reduced by up to 30% in designs where fins were added to the top disk cavity whereas a smaller reduction in stress of up to 1.47% is achieved for designs where fins were added to the bottom disk domain when compared with the existing baseline design. These demonstrated that the effects of heat transfer coefficients on maximum thermal stress are more drastic at the upper region of the disk.
author2 Chow Wai Tuck
author_facet Chow Wai Tuck
Tan, Qi Xiang
format Final Year Project
author Tan, Qi Xiang
author_sort Tan, Qi Xiang
title Multidisciplinary design of turbine disks
title_short Multidisciplinary design of turbine disks
title_full Multidisciplinary design of turbine disks
title_fullStr Multidisciplinary design of turbine disks
title_full_unstemmed Multidisciplinary design of turbine disks
title_sort multidisciplinary design of turbine disks
publisher Nanyang Technological University
publishDate 2020
url https://hdl.handle.net/10356/141022
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