- Corsi in lingua inglese
- Master's Degree in AEROSPACE ENGINEERING
- AERONAUTIC PROPULSION MOD. 1 (Int) SPACE PROPULSION MOD. 2
- AERONAUTIC PROPULSION MOD. 1
AERONAUTIC PROPULSION MOD. 1
- Teaching in italian
- AERONAUTIC PROPULSION MOD. 1 C.I.
- Teaching
- AERONAUTIC PROPULSION MOD. 1
- Subject area
- ING-IND/07
- Reference degree course
- AEROSPACE ENGINEERING
- Course type
- Master's Degree
- Credits
- 6.0
- Teaching hours
- Frontal Hours: 54.0
- Academic year
- 2020/2021
- Year taught
- 2020/2021
- Course year
- 1
- Language
- ENGLISH
- Curriculum
- Percorso comune
- Reference professor for teaching
- DE GIORGI Maria Grazia
Teaching description
-Fluid dynamic and fluid machinery
Aircraft turbine engines are discussed, both those primarily suitable for military aircraft and commercial transport. The aim is to foster an understanding of the characteristics of these diverse propulsion systems from the basic principles, showing how each uses sources of propulsive mass and energy to produce thrust.
The main topics will be: Introduction to air-breathing (gas turbines, ramjets, ducted rockets, scramjets) jet propulsion systems. Prediction of thrust, combustion reactions, specific fuel consumption and operating performance. Aerothermodynamics of inlets, combustors, nozzles, compressors, turbines. Review of space propulsion systems. Introduction to alternative future space propulsion systems. Chemical rocket and jet engine combustion including thermochemistry, chemical kinetics and the combustion chamber and instabilities. Jet engine noise and emissions. Overview of jet engine systems such as thrust reversal, internal air, starting and ignition, controls and instrumentation, power plant testing and installation, maintenance.
A goal is to introduce you to the methods of mathematical modeling of propulsion systems and then to use these modeling techniques to develop an understanding of the characteristics of the several types of propulsion systems treated.
The modeling uses thermodynamic arguments based on the First and Second Laws, and fluid mechanical principles that enable the linking of the thermodynamic behavior to the geometry of the propulsion devices.
Mail goals are:
1 Gain knowledge of different types of aero-engines (turbojets, turbofans, ramjets) and to understand the aerodynamic and thermodynamic characteristics of major engine components.
2 Develop the knowledge and skills to analytically and numerically solve problems related to aerospace propulsion systems.
3 Develop skills in working independently.
4 Develop skills in critical evaluation of scientific literature.
5 Develop skills in planning and presentation of scientific talks and reports.
Theory and practical activities (Tutorials devoted to discussion and problem solving referred to the aeroengine.)
The final exam consist of two part:
1)Written and oral examination covering all material covered in course
2)assignments and individual project
1) Review of thermodynamics and Introduction of Propulsion: Review, Mixtures of gases, Thermodynamic cycles, Combustion thermodynamics
2)Types of Airbreathing Engines. Aircraft Propulsion Requirements. Turbojet systems, turbofan systems, turboprops/propfans systems, ramjet systems, scramjet systems
3)Elements of Thermodynamics for Aero Propulsion ; Ideal & Real Engine Cycle Analysis. Parametric Cycle Analysis.
4) Subsonic & Supersonic Inlets.
5) Turbomachiney: Axial Flow Compressors and Axial Flow Turbines.
6) Combustors.
7) Nozzles.
8) Airbreathing Engine System Considerations.
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Aerothermodynamics of Gas Turbine and Rocket Propulsion Gordon C. Oates eISBN: 978-1-60086-134-5 print ISBN: 978-1-56347-241-1 DOI: 10.2514/4.861345
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Hill, P., and Peterson, C., Mechanics and Thermodynamics of Propulsion, Addison-Wesley Publishing Co., 1992,
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Course notes
Semester
Second Semester (dal 01/03/2021 al 11/06/2021)
Exam type
Type of assessment
Oral
Course timetable
https://easyroom.unisalento.it/Orario
Parent teaching
AERONAUTIC PROPULSION MOD. 1 (Int) SPACE PROPULSION MOD. 2 (LM52)