Faculty Of Mechanical Engineering — Course Catalog — B.Sc .

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies Skill Praxis B - MFB ID: BSc-0022 teaching professor: Милош В. Марко level of studies: B.Sc. (undergraduate) academic studies ECTS credits: 1 final exam: project design parent department: MFB goals Practical expereance in ambient similar to the ambient where the graduated student mechanical engineer will realize his own proffesioanal carrier. Recognizing the basic functioning of the bussines systems especially in domain of development, design and manufacturing of the mechanical systems. learning outcomes Students can reach practical expereances about the organization and functioning the bussines systems that deal in mechanical engineering. Student can be introdused in bussines comunication, design processes, development processes and manufacturing. theoretical teaching practical teaching The skill praxis is organized in a way which is the most appropriate for the student. Practical work must be realized in the company where the mechanical engineering is the primary occupation. What the student will work, see or follow must be defined in coordination with the proffessor. Generally, student can realize practical work in: manufacturing companies, design companies, companies which worh maintenance in mechanics or in laboratories that belong to the Mechanical faculty. After finishing the practical work, the student must prepare the Report and this Report needs to be defended in front of professor. prerequisite learning resources Initial resources are laboratories that belongs to the Mechanical faculty. number of hours total number of hours: 46 active teaching (theoretical) lectures: 0 active teaching (practical) auditory exercises: 0 laboratory exercises: 0 calculation tasks: 0 seminar works: 0 project design: 0 10

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies consultations: 0 discussion and workshop: 0 research: 0 knowledge checks check and assessment of calculation tasks: 0 check and assessment of lab reports: 0 check and assessment of seminar works: 0 check and assessment of projects: 0 colloquium, with assessment: 0 test, with assessment: 0 final exam: 46 assessment of knowledge (maximum number of points - 100) feedback during course study: 0 test/colloquium: 0 laboratory exercises: 0 calculation tasks: 0 seminar works: 0 project design: 0 final exam: 100 requirements to take the exam (number of points): 0 references 11

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies aerospace engineering AERODYNAMIC CONSTRUCTIONS Aerodynamics Aerodynamics Aircraft propulsion and systems Computational methods in aeronautics Design and Aircraft Production Technology FEM Analysis Fundamentals of aerotechnics Introduction to engineering simulations Introduction to engineering simulations Light and Composite Aircraft Structures Light and Composite Structures Mechanics of Flight professional practice B - AVIATION Structural Analysis of Flying Vehicles Theory of Elasticity Windturbines 12

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies AERODYNAMIC CONSTRUCTIONS ID: BSc-0429 teaching professor: Стефановић А. Зоран level of studies: B.Sc. (undergraduate) academic studies ECTS credits: 6 final exam: written parent department: aerospace engineering goals The aim of this course is to introduce students to basic concepts in applied aerodynamics. The emphasis is on the aerodynamics of aircraft, but will consider the role in the construction of wind turbines, cars, etc. Concept of aerodynamic loads will be analyzed and its importance not only when it comes to aircraft parts, but also buildings, bridges, ect. learning outcomes After passing the course student is expected to discuss the basic laws of aerodynamics and know how to apply them to solve practical problems. At the same time it is expected that sudent recognize problems, and implementation of these results in other areas of technics. theoretical teaching Course content consists of theoretical and practical part. Theoretical part analyzes the following topics: - The role and the case study of aerodynamics, slender body concept, aerodynamic forces and aerodynamic torque, etc.; - Airfoil (basic geometric features, characteristics, notation and families); - Wings (geometric and aerodynamic characteristics), comand surfaces (flaps, brakes, ailerons, slats, etc.); - Aircraft aerodynamic scheme; - Structural and aerodynamic characteristics of the propellers, rotors and wind turbines. practical teaching Пractical part of course demonstrate the numerical examples in the area covered in the lectures. Practical work of students is realized through a virtual classroom available 24 hours (internet - software MOODLE). In the workshop students have approach to the professor's written notes, lectures, assignments and tests for practice. Practical training includes two homeworks of the student (an individual and a collective in group within the group to which students are divided). In the first student perform calculation of the aerodynamic characteristics of the airplane, and the second is the essay that exposes the public. In practical training exists excursion - students visit to Aviation Museum - Surčin. prerequisite None learning resources In the Course exists a virtual classroom on the Internet. MOODLE is used to program. Students are entered electronically into a classroom and have approach to the professor notes, quizes and additional material advised by professor. 13

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies number of hours total number of hours: 75 active teaching (theoretical) lectures: 30 active teaching (practical) auditory exercises: 10 laboratory exercises: 0 calculation tasks: 5 seminar works: 0 project design: 0 consultations: 10 discussion and workshop: 5 research: 0 knowledge checks check and assessment of calculation tasks: 0 check and assessment of lab reports: 0 check and assessment of seminar works: 3 check and assessment of projects: 2 colloquium, with assessment: 0 test, with assessment: 5 final exam: 5 assessment of knowledge (maximum number of points - 100) feedback during course study: 15 test/colloquium: 15 laboratory exercises: 0 calculation tasks: 20 seminar works: 20 project design: 0 final exam: 30 requirements to take the exam (number of points): 25 references 14

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies Aerodynamics ID: BSc-0085 teaching professor: Пешић М. Славко level of studies: B.Sc. (undergraduate) academic studies ECTS credits: 6 final exam: written parent department: aerospace engineering goals 1. Introduction to basic laws of aerodynamics and its application in solving practical problems. 2. Introduction to the wind tunnels, their use and their role in the aerodynamic design of aircraft. 3. Introduction to basic aerodynamic aircraft scheme. 4. Introduction to basic aerodynamic characteristics of aircraft. learning outcomes 1. Mastering the basic theoretical knowledge of aerodynamics. 2. Application of learned theoretical knowledge in the practical problems solving. 3. Apprehension of the basic aerodynamic aircraft scheme. 4. Apprehension of the basic aerodynamic characteristics of aircraft. theoretical teaching Lesson 1: Modeling of flow field Lesson 2: The equation of energy in compressible flow Lesson 3: The law of conservation of mass in the compressible flow Lesson 4: The waves in compressible flow Lesson 5: The expansion wave Lesson 6: The normal shock wave Lesson 7: Oblique shock wave Lesson 8: Flow through the nozzle Lesson 9: Speed measurement in the compressible flow Lesson 10: Airfoils in the supersonic flow field Lesson 11: Wind tunnels Lesson 12: Methods of measurement in wind tunnels Lesson 13: Aerodynamic aircraft scheme Lesson 14: Aerodynamic characteristics of aircraft practical teaching In the practical part of the course basics laws of aerodynamics are used for solving and analysis of the characteristic numerical examples. Practical work of students is carried out through the mandatory lab classes as well as through the virtual workshop (program MOODLE) which is available 24 hours. In the virtual workshop written notes of lectures, exercises and test problems are available for students to check their current knowledge. Practical part of the course includes two different homeworks. A homework assignment for each student individually, and a group homework assignment, which is carried out in small groups (up to five students per group). Practical training includes an excursion, a tour of the wind tunnel complex in the aerodynamics sector of the Military Technical Institute. 15

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies prerequisite No special conditions learning resources Lectures in electronic form, the demo movies, and simulations available through the virtual workshop (program MOODLE), internet resources. number of hours total number of hours: 75 active teaching (theoretical) lectures: 30 active teaching (practical) auditory exercises: 10 laboratory exercises: 0 calculation tasks: 5 seminar works: 0 project design: 0 consultations: 10 discussion and workshop: 5 research: 0 knowledge checks check and assessment of calculation tasks: 0 check and assessment of lab reports: 0 check and assessment of seminar works: 2 check and assessment of projects: 3 colloquium, with assessment: 0 test, with assessment: 5 final exam: 5 assessment of knowledge (maximum number of points - 100) feedback during course study: 15 test/colloquium: 25 laboratory exercises: 0 calculation tasks: 0 seminar works: 15 project design: 15 final exam: 30 requirements to take the exam (number of points): 21 references 16

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies Aerodynamics ID: BSc-0610 teaching professor: Костић А. Иван level of studies: B.Sc. (undergraduate) academic studies ECTS credits: 2 final exam: written parent department: aerospace engineering goals The aim is that after attended course in Aerodynamics, students become familiar with the basic laws of aerodynamics, and their application in slowing practical problems. Specific issues and phenomena of compressible flow are analyzed. Students acquire knowledge about the design concepts of aircraft for different speed domains, as well as about the fundamentals of the road vehicle aerodynamics. Within the course, students also become familiar with the basics of experimental aerodynamics, and its application in aeronautical and non-aeronautical testing. learning outcomes After accomplishing the course, students acquire knowledge in the domain of aerodynamics, with special attention paid on compressible flow domain, as well as the understanding of basic aircraft design schemes and automobile aerodynamics. They also gain knowledge about the basics of experimental aerodynamics, and its application not only in the domain of aviation, but also in other technical branches. theoretical teaching Lesson 1: Flow field modeling Lesson 2: Compressible flow and waves in compressible flow Lesson 3: Aerodynamic design schemes of aircraft and road vehicles Lesson 4: Subsonic, transonic and supersonic wind tunnels Lesson 5: Wind tunnel measurements practical teaching In practical part, presented theoretical laws are demonstrated through the solutions and analyses of selected numerical problems. Beside the mandatory lab classes, practical activities are also accomplished through the virtual workshop (program MOODLE), which is available 24 hours. In the virtual workshop, written notes of lectures, exercises and test problems are available for students to check their current knowledge. Practical part includes consulting and discussions of one homework, which is accomplished through smaller student groups (of up to five students per each group). Practical training also includes an excursion, a tour of the wind tunnel complex in the aerodynamics sector of the Military Technical Institute. prerequisite No special conditions, but attended course in Aerodynamic Design is recommended. learning resources Lectures in electronic form, demo movies and clips, and graphical simulations available through the virtual workshop (program MOODLE), internet resources. number of hours 17

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies total number of hours: 30 active teaching (theoretical) lectures: 12 active teaching (practical) auditory exercises: 5 laboratory exercises: 0 calculation tasks: 0 seminar works: 0 project design: 0 consultations: 5 discussion and workshop: 2 research: 0 knowledge checks check and assessment of calculation tasks: 0 check and assessment of lab reports: 0 check and assessment of seminar works: 1 check and assessment of projects: 0 colloquium, with assessment: 0 test, with assessment: 0 final exam: 5 assessment of knowledge (maximum number of points - 100) feedback during course study: 18 test/colloquium: 32 laboratory exercises: 0 calculation tasks: 0 seminar works: 20 project design: 0 final exam: 30 requirements to take the exam (number of points): 21 references 18

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies Aircraft propulsion and systems ID: BSc-0053 teaching professor: Јанковић М. Јован level of studies: B.Sc. (undergraduate) academic studies ECTS credits: 6 final exam: written oral parent department: aerospace engineering goals Subject task is to introduce students with aircraft equipment and power systems, their functions, structures and basic principals. Subject enables global introduction of students into all aircraft and power systems, and its integrity. learning outcomes By the subject student gets knowledges and understandings about existing aircraft and power systems of various types. These knowledges enables understending of aircraft and power systems if they are oriented to other aeronautical fields, or to further specialization in this aeria. theoretical teaching Hidraulic aircraft systems, Fuel aircraft systems, Pneumatic aircraft systems, Enviromental aircraft systems, Anti-icing aircraft systems, Aircraft electrical systems, Aircraft cabin systems, Avionics, Aircraft Control systems, Aircraft safety systems, . practical teaching Practical teaching is related to prezenting samples, analysis and discusion with students in the fields previously treated theoretically. Hidraulic aircraft systems, Fuel aircraft systems, Pneumatic aircraft systems, Enviromental aircraft systems. Avionics, Control aircraft systems, Electrical aircraft systems, Aircraft safety systems, Antiicing aircraft systems. prerequisite Declared by the curiculum of study programe/modul. learning resources Various written forms from teching. Various books and papers. number of hours total number of hours: 75 active teaching (theoretical) lectures: 30 active teaching (practical) auditory exercises: 30 19

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies laboratory exercises: 0 calculation tasks: 0 seminar works: 0 project design: 0 consultations: 0 discussion and workshop: 0 research: 0 knowledge checks check and assessment of calculation tasks: 0 check and assessment of lab reports: 0 check and assessment of seminar works: 0 check and assessment of projects: 0 colloquium, with assessment: 10 test, with assessment: 0 final exam: 5 assessment of knowledge (maximum number of points - 100) feedback during course study: 10 test/colloquium: 60 laboratory exercises: 0 calculation tasks: 0 seminar works: 0 project design: 0 final exam: 30 requirements to take the exam (number of points): 30 references 20

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies Computational methods in aeronautics ID: BSc-0568 teaching professor: Симоновић М. Александар level of studies: B.Sc. (undergraduate) academic studies ECTS credits: 4 final exam: written parent department: aerospace engineering goals Introducing students to the basics of computer applications in simulations and computations of aeronautical problems. The subject is organized so that several typical (model) problems are completely solved step-by-step from start to finish. learning outcomes By mastering the curriculum a student gains specific skills: thorough knowledge and understanding of numerical methods ability to use and apply basic numerical methods for solving ODE, finite difference and finite elements methods correlation between fundamentals in mathematics, programming, mechanics, fluid mechanics and construction analysis theoretical teaching Determination of geometrical characteristics of sections Parameters of compressible flow - Fundamental equations for one-dimensional compressible flow Calculation of the flow around a cone (example of solving a problem modeled by ODE) Simulation of plane take-off (also example of solving a problem modeled by ODE, application of interpolation methods to aerodynamic characteristics of aircrafts) FEM calculation of lattice structures (example of solving sparse systems of equations with many unknowns) practical teaching Determination of geometrical characteristics of sections - using a program for calculating the geometrical characteristics of sections Parameters of compressible flow - an interactive program for parameters of compressible flow Calculation of the flow around a cone (example of solving a problem modeled by ODE) computational problem solving, obtained results and analysis Simulation of plane take-off (also example of solving a problem modeled by ODE, application of interpolation methods to aerodynamic characteristics of aircrafts) - a program for calculating take-off distance and velocity FEM calculation of lattice structures (example of solving sparse systems of equations with many unknowns) - a program for calculating stresses of two-dimensional lattices 21

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies prerequisite There are no necessary conditions for attending the subject. learning resources 1. Petrovic Z, Stupar S, CFD one, Faculty of Mechanical Engineering, 1992, KPN 2. Additional materials (lecture hand-writings, problem settings, task solving guidelines), DVL 3. 452, Computer laboratory SimLab, IKT/CAH 4. FORTRAN, Computer laboratory SimLab, IKT/PPO number of hours total number of hours: 45 active teaching (theoretical) lectures: 17 active teaching (practical) auditory exercises: 8 laboratory exercises: 4 calculation tasks: 0 seminar works: 4 project design: 0 consultations: 0 discussion and workshop: 0 research: 0 knowledge checks check and assessment of calculation tasks: 0 check and assessment of lab reports: 0 check and assessment of seminar works: 4 check and assessment of projects: 0 colloquium, with assessment: 3 test, with assessment: 0 final exam: 5 assessment of knowledge (maximum number of points - 100) feedback during course study: 10 test/colloquium: 20 laboratory exercises: 20 calculation tasks: 0 seminar works: 20 project design: 0 final exam: 30 requirements to take the exam (number of points): 30 references 22

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies 23

Faculty of Me anical engineering — course catalog — B.Sc. (undergraduate) academic studies Design and Aircraft Production Technology ID: BSc-025

mechanical engineering, Railway mechanical engineering, Welding and welded structures, Engineering of biotechnical systems, Industrial engineering, Information technologies, Motor vehicles, Internal combustion engines, Food industry engineering, Production engineering, Process engineering and environment protection, Weapon systems, Thermal power