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- Type of Document: M.Sc. Thesis
- Language: Farsi
- Document No: 45486 (08)
- University: Sharif University of Technology
- Department: Mechanical Engineering
- Advisor(s): Hajilou Benisi, Ali
- Abstract:
- Axial-flow compressor is one of the most basic components of gas turbine engines. Consequently, it is essential to design this machine appropriately. Full three dimensional analyses of axial-flow compressors is time consuming due to the flow field complexity, so a method with minimum running time and producing an acceptable design is required. One dimensional design method is a low cost procedure with acceptable results for preliminary stages of design. It receives inlet flow conditions, such as total pressure ratio, mass flow and rotational speed and designs a compressor which satisfies the desired input data. Too many efforts have been accomplished to predict energy losses, design incidence angle, design deviation angle and stall condition. They are theoretical-experimental researches. In present work, the models of Lieblein, Koch-Smith, Herrig, Johnsen-Bullock, Horlock, Pollard-Gostelow, Aungier and Reneau are implemented to predict the compressor losses, incidence angle, deviation angle, stall and surge conditions.First, the performance of a single stage axial-flow compressor is predicted using one-dimensional modeling approach. Then the results are validated with experimental and three-dimensional modeling results. Maximum differences of one-dimensional modeling results and experimental results are 2.1% and 3.4% for pressure ratio and isentropic efficiency respectively. After validating the theoretical-experimental relations which are used for one-dimensional modeling with experimental and 3D modeling they are used to design a two stage axial-flow compressor. A two stage axial flow compressor with defined geometry is redesigned and its characteristic curves are determined by performance prediction program. The results show 14% diameter increase and 25% decrease of axial length of the compressor. Also, the redesigned compressor produces more pressure ratio than the original.This design program is capable of designing through three geometric methods: constant mean diameter, constant tip diameter and constant hub diameter. At the end, these three design procedures are compared resulting, the CHD method produces more pressure ratio and isentropic efficiency
- Keywords:
- Three Dimensional Modeling ; Axial Compressor ; One-Dimentional Modeling ; Axial Compressor Design ; Design and off-Design Condition
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