Nuclear Power Engineering (FSI-EJE)

Academic year 2018/2019
Supervisor: doc. Ing. Jan Fiedler, Dr.  
Supervising institute: all courses guaranted by this institute
Teaching language: Czech
Aims of the course unit:
The aim of this subject is to inform students
about nuclear power engineering basis, nuclear fuel cycles basis
and its development aproaches. Further aim is to teach students
several important nuclear reactors designs, nuclear safety and
introduce some relations between nuclear power engineering and
environment.
Learning outcomes and competences:
This subject learn students bases of nuclear energetics to undertant its society development importance, to be well informed in various concepts of nuclear reactors and power stations and to observe nuclear safety and effectiveness. Further students learn basis of nuclear fuel cycle.
Prerequisites:
Power equipments heat circulation, energy transformations, heat transfer.
Course contents:
The subject makes the students familiar with the elementary principles of nuclear energy conversion into the thermal, mechanical and electrical energies and with the fundamental and detailed design of reactors and nuclear power plant equipment where the above conversions of energies take place. Attention is devoted to the fundaments of nuclear fuel preparation, manufacture, reprocessing, storage and transmutation and nuclear wastes management with regard to the Czech Atomic Law. Safety, technical tools to meet the safety requirements as well as enviromental problems of nuclear power plants are studied. Ways of nuclear power plant upgrades by passive safety systems are analysed.
Teaching methods and criteria:
The course is taught through lectures explaining the basic principles and theory of the discipline. Exercises are focused on practical topics presented in lectures.
Assesment methods and criteria linked to learning outcomes:
Credit: Active seminars attendance. Active solving of assigned problems.
Exam: Written + oral. The aim of exam is to check students knowledge of lectured subject matter. Written exam consist in solving of 3 problems. Oral exam checks theoretical knowledge of students in nuclear energetics problems.
Controlled participation in lessons:
Lecture attendance is not obligatory.
Credit attendance is obligatory and it will be checked. Maximum number of nonexcused absences are 2. In case of higher absence is the student obligated to do an individual work in accordance with teachers requirements.
Type of course unit:
    Lecture  13 × 3 hrs. optionally                  
    Exercise  13 × 2 hrs. compulsory                  
Course curriculum:
    Lecture 1. Basic definions, radioactive transmutations.
2. Nuclear reactions and its characteristics.
3. Nucleus fission, fission balance, crossections.
4. Types and construction of nuclear reactors.
5. Nuclear reactor calculation bases, crytical equation, equation of 4 coefficients.
6. Reactor control, measurement and screening.
7. Nuclear power stations with PWR, BWR, FBR, HTGR, ADTT types of reactor.
8. Nuclear chain fission reation kinetics, heat generation and removal.
9. Reactor operation and control, core materials.
10. Nuclear power stations machine equimpent
11. Nuclear spent fuel treatment, fuel cycles.
12. Nuclear safety, defence in depth principles.
13. nuclear energetics development prospects, nuclear transmutations.

    Exercise 1. Basic definions.
2. Calculation of nuclear reactions.
3. Fuel nucleus fission balance.
4. Nuclear reactors charakteristic.
5. Nuclear reactor crytical parameters calculation.
6. Reactor control equipment.
7. Nuclear reactor start-up, performance and shut-down.
8. Reactor heat generation calculation.
9. Reactor cooling calculation.
10. Nuclear power stations machine equimpent
11. Calculation of nuclear plant heat cycle.
12. Nuclear safety in relation to reactor practical performance.
13. Nuclear transmutations technology and equipment introduction.
Literature - fundamental:
1. KLIK, František a Jaroslav DALIBA. Jaderná energetika. Vyd. 2. Praha: Vydavatelství ČVUT, 2002, 189 s. ISBN 80-010-2550-0.
2. Sazima, Kmoníček, Schneller a kol.: Teplo. SNTL 1989
3. Butterworth-Heinemann:Nuclear energy: an introduction to the concepts, systems, and applications of nuclear processes.Boston 2001. 5th ed.490 s. ISBN 0-7506-7136-X
4. MURRAY, Raymond L. Nuclear energy: an introduction to the concepts, systems, and applications of nuclear processes. 6th ed. Oxford: Butterworth-Heinemann, 2008. ISBN 978-012-3705-471
Literature - recommended:
1. DOLEŽAL, Jaroslav, Jiří ŠŤASTNÝ, Jan ŠPETLÍK, Stanislav BOUČEK a Zbyněk BRETTSCHNEIDER. Jaderné a klasické elektrárny. Vyd. 1. Praha: České vysoké učení technické v Praze, 2011, 259 s. ISBN 978-80-01-04936-5.
2. STACEY, Weston M. Nuclear reactor physics. 2nd ed., completely rev. and enlarged. Weinheim: Wiley-VCH, c2007, xxviii, 706 s. ISBN 978-3-527-40679-1.
The study programmes with the given course:
Programme Study form Branch Spec. Final classification   Course-unit credits     Obligation     Level     Year     Semester  
B3S-P full-time study B-EPP Power Engineering, Processes and Environment -- Cr,Ex 5 Compulsory-optional 1 3 S