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Introduction » Students » Study programs and subjects

Study programs and subjects

Detailed information about study fields (study programs, fields / spec., Plans, their segments, blocks and subjects) and subjects taught at KEZ (syllabi, literature, schedule, students of the course and listed dates) can be found on the STAG portal.

The Department of Power Equipment provides teaching in

1. bachelor study program B0715A270008STR Mechanical Engineering

subjects:

  • Thermodynamics and heat transfer KEZ / TST

The course describes the basic knowledge in the field of thermomechanics and heat transfer issues applied mainly to the technical sciences of mechanical engineering. It deals with issues of application of thermodynamic processes in device design, understanding of function and expression of efficiency of processes and machines.

  • Fluid mechanics KEZ / MT

Basic properties of fluids, hydrostatics, relative equilibrium, hydrodynamics of viscous and viscous incompressible fluids, laminar and turbulent flow, hydraulic losses, flow of gases and vapors, dynamic effects of fluid flow, equipment for transport and compression of fluids.

  • Technical measurements KEZ / TM

The aim of the course is to provide systematic knowledge of experimental and measuring techniques in the field of mechanical engineering, but also in the field of research and development.

 

final thesis:

  • Bachelor Seminar KEZ / BCPS, Bachelor Thesis I KEZ / BCP1, Bachelor Thesis II KEZ / BCP2

The focus of the bachelor's thesis results from the research activities of the department or from an industrial assignment. These are practical solutions of a completely individual nature.

2nd master's study program N0715A270019 Construction of machines and equipment - field of study Power Equipment

subjects:

  • Heat and mass transfer KEZ / PTH


The basic mechanisms of transmission phenomena are taught within the course. The main topics are: Balance equations, Euler's and Lagrange's description, basic mechanisms of heat transfer, stationary and non-stationary heat conduction, convective heat transfer, heat transfer during change of state, heat transfer by radiation, methods of calculation of irradiation coefficient. Mass transfer by molecular diffusion, convective mass transfer, simultaneous heat and mass transfer, Reynolds analogy, Chilton-Colburn analogy.

  • Experimental methods in fluid mechanics and thermomechanics KEZ / EXMT


The course deals with the theoretical basis and practical measurements using experimental methods.

  • Applied fluid mechanics KEZ / AMT


The course expands students' knowledge of fluid mechanics in the areas of compressible fluid flow - gas dynamics (in nozzles and diffusers with the occurrence of shock waves, flow with friction and heat transfer, visualization of gas flow), viscous flow (turbulent flow, its calculations and measurements, examples of shear zones, hot wire velocity measurement) and jet machines (fans, turbines and ejectors).

  • Construction of KEZ / TSK heat engines


This course provides basic information about energy and energy machines. For individual types of energy machines, teaching is guided by an effort for a design approach, ie in addition to a thorough understanding of the basics of circulation and the determination of the main dimensions, selection of suitable construction materials for the purpose, etc.

  • Piping systems and their regulation KEZ / PSR


Design and calculation of piping systems for the transport of liquids, gases and vapors. Functional characteristics and properties of some groups of regulatory bodies.

  • Technical equipment of KEZ / TZAB buildings


The course acquaints students with the basics of design of ventilation and air conditioning equipment. It is a definition of parameters determining the microclimate of buildings, thermal properties of buildings, calculation of thermal load of buildings, basic calculations of air conditioning for air conditioning, design of pipelines for air distribution, principles of air filtration, elements of ventilation and air conditioning equipment, cold and heat sources for air conditioning, air conditioning systems, principles of heat recovery. The course also introduces students to the design and calculation procedures of basic types of heating systems, their components, including selected sources for heating and the design of hot air heating system.

final thesis:

  • Project I KEZ / PR1 * M, Project II KEZ / PR2 * M, Diploma Thesis 1 KEZ / DP1 * M, Diploma Thesis 2 KEZ / DP2 * M, Diploma Thesis III KEZ / DP3 * M


The diploma thesis is a solution to a theoretical or practical problem with an indication of the achieved results, or construction project. A part of the solution can also be a functional sample of the designed device or its part. The student also has the right to design the topic of his diploma thesis himself.

3rd master's study program N0715A270020 Applied Mechanics - Fluid Mechanics

subjects:

  • Heat and mass transfer KEZ / PTH


The basic mechanisms of transmission phenomena are taught within the course. The main topics are: Balance equations, Euler's and Lagrange's description, basic mechanisms of heat transfer, stationary and non-stationary heat conduction, convective heat transfer, heat transfer during change of state, heat transfer by radiation, methods of calculation of irradiation coefficient. Mass transfer by molecular diffusion, convective mass transfer, simultaneous heat and mass transfer, Reynolds analogy, Chilton-Colburn analogy.

  • Applied fluid mechanics KEZ / AMT


The course expands students' knowledge of fluid mechanics in the areas of compressible fluid flow - gas dynamics (in nozzles and diffusers with the occurrence of shock waves, flow with friction and heat transfer, visualization of gas flow), viscous flow (turbulent flow, its calculations and measurements, examples of shear zones, hot wire velocity measurement) and jet machines (fans, turbines and ejectors).

  • Computational methods in KEZ / VMM mechanics


Basic equations and relations for fluid flow simulation, formulation of mathematical models, boundary and initial conditions, computational network generation and its quality, discretization and accuracy of solutions, convergence of problems and methods to improve convergence, finite element method, calculation and modeling of turbulence, turbulent RANS models , LES and hybrid turbulent models, parallel computations and its efficiency. Multiphase flow problems for incompressible fluid. Examples of CFDs for various problems.

  • Thermophysical properties of KEZ / TVL materials


The student will learn to actively use modern methods of mathematical description and prediction of thermophysical properties of substances, especially technical working media. Equations of state, thermodynamic properties, transfer properties, phase equilibrium and initial stages of phase transition (nucleation), connection to thermodynamics and fluid mechanics in the exercise.

  • Selected articles from thermodynamics KEZ / VST


Thermodynamic properties of real substances. Energy and entropic forms of Gibbs fundamental equations and the use of properties of energy functions to describe thermodynamic properties. Thermo-dynamic properties during phase changes. Thermodynamic properties of ideal and real mixtures. Application of solution procedures to technical problems.

  • Excursion KEZ / EX * M


Weekly excursions to energy facilities.

  • Professional practice KEZ / OP * M


Three-week professional practice in energy facilities.

  • Construction of KEZ / TSAM heat engines


This course provides basic information about energy and energy machines. For individual types of energy machines, teaching is guided by an effort for a design approach, ie in addition to a thorough understanding of the basics of circulation and the determination of the main dimensions, selection of suitable construction materials for the purpose, etc.

  • Cavitation KEZ / KAV


Cavitation is a phenomenon associated with the formation, extinction and activities of macroscopic cavities in a fluid. The course introduces students to the issues of cavitation, cavitation damage and the use of cavitation. Emphasis is placed primarily on the application of cavitation knowledge in the design of hydrodynamic equipment, such as turbines and pumps, and also in the design of equipment using cavitation in environmental protection and industrial applications. Within the course, students will get acquainted with the use of cavitation in biomedical applications, such as eye surgery, tumor surgery and intensification of drug delivery in the treatment of cancer.

  • Boundary layers and turbulence KEZ / MVTT


Boundary layer theory, turbolizers in the boundary layer, transition to turbulence. Characteristics of stochastic processes, frequency spectra of fluctuations, overview of higher turbulence models. Thermoanemometric methods of analysis. LDA and PIV methods.

final thesis:

  • Project I KEZ / PR1 * A, Project II KEZ / PR2 * A, Diploma Thesis 1 KEZ / DP1 * A, Diploma Thesis 2 KEZ / DP2 * A, Diploma Thesis III KEZ / DP3 * A.


The diploma thesis is a solution to a theoretical or practical problem with an indication of the achieved results, or construction project. A part of the solution can also be a functional sample of the designed device or its part. The student also has the right to design the topic of his diploma thesis himself.

4. in doctoral study programs

  • P2301 Mechanical Engineering - field 3901V003 Applied Mechanics - specialization Fluid Mechanics and Thermodynamics
  • P2302 Machines and equipment - field 2302V010 - specialization Equipment for thermal technology
  • P0715D270004 Applied Mechanics