FACULTY OF MECHANICAL ENGINEERING

FACULTY OF MECHANICAL ENGINEERING

DEAN Prof. Ing. Petr Zuna, CSc.VICE-DEANS:EDUCATION - basic studies: Doc. Ing. Josef Adamec, CSc.EDUCATION - specialized studies: Doc. Ing. Jan Vojtek, CSc.SCIENCE AND RESEARCH: Doc. Ing. Jiří Hemerka, CSc.INTERNATIONAL RELATIONS: Doc. Ing. Milan Hofreiter, CSc.DEVELOPMENT: Doc. Ing. Luboš Janko, CSc.

Address: Technická 4, 166 07 Praha 6 Phone: (+420 2) 311 9813, 2435 1111 Fax: (+420 2) 311 1261 E-mail: dean@fsid.cvut.cz http://www.fsid.cvut.cz

Contact persons: Ing. Petr Holmer, CSc, International Relations Office, directorPhone: (+420 2) 2435 2889 Fax: (+420 2) 2431 0292 E-mail: holmer @ fsid.cvut.cz Doc.Ing.Eva Vesela, CSc, Study DepartmentPhone: (+420 2) 2435 2764 E-mail: vesela @ fsid.cvut.cz _______________________________________________________________________________________________

201 Department of Technical Mathematics Head: Prof. RNDr. Karel Kozel, DrSc.Address: Karlovo nám. 13, 121 35 Praha 2 Phone: (+420 2) 2435 7365, Fax: (+420 2) 2492 06 97, E-mail: pecenkov@fsik.cvut.cz

202 Department of Applied PhysicsHead: Prof. RNDr. Bruno Sopko, DrSc.Address: Technická 4, 166 07 Praha 6Phone: (+420 2) 2435 2427, Fax: (+420 2) 311 3657, E-mail: sopko@fsid.cvut.cz203 Department of Physical Education Head: PhDr. Jaroslav Schmid, CSc.Address: Karlovo nám. 13, 121 35 Praha 2 Phone: (+420 2) 2435 7650, 2435 765, Fax: (+420 2) 29 03 02, E-mail: kriz@fsik.cvut.cz

204 Department of LanguagesHead: PhDr. Hana Kybicová, CSc.Address: Horská 4, 128 03 Praha 2Phone: (+420 2) 2491 5319, Fax: (+420 2) 311 2768, E-mail: kybicova@fsih.cvut.cz

205 Department of MechanicsHead: Prof. Ing. Svatava Konvičková, CSc.Address: Technická 4, 166 07 Praha 6 Phone: (+420 2) 2435 2511, Fax: (+420 2) 2431 0292, E-mail: konvicko@fsid.cvut.cz

207 Department of Fluid Dynamics and Power EngineeringHead: Prof. Ing. Václav Petr, DrSc.Address: Technická 4, 166 07 Praha 6 Phone: (+420 2) 2435 2539, Fax: (+420 2) 2435 3705, E-mail: dlouhy@fsid.cvut.cz

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FACULTY OF MECHANICAL ENGINEERING

208 Department of Production Machines and MechanismsHead: Prof. Ing. Jaroslav Talácko, CSc.Address: Horská 4, 128 03 Praha 2Phone: (+420 2) 2435 3540, Fax: (+420 2) 2491 3540, E-mail: talacko@fsih.cvut.cz

210 Department of Instrumentation and Control EngineeringHead: Prof. Ing. Pavel Zítek, DrSc.Address: Technická 4, 166 07 Praha 6Phone: (+420 2) 2435 2564, 311 641, Fax: (+420 2) 2431 0292, E-mail: zitek@fsid.cvut.cz

216 Department of Environmental Engineering Head: Doc. Ing. Richard Nový, CSc.Address: Technická 4, 166 07 Praha 6Phone: (+420 2) 2435 2478, 2435 248,Fax: (+420 2) 2435 5606, E-mail: novy@fsid.cvut.cz

218 Department of Process EngineeringHead: Prof. Ing. František Rieger, DrSc.Address: Technická 4, 166 07 Praha 6Phone: (+420 2) 2435 2548, Fax: (+420 2) 2431 0292, E-mail: rieger@fsid.cvut.cz

220 Department of Automotive and Aerospace EngineeringHead: Prof. Ing. Jan Macek, DrSc.Address: Technická 4, 166 07 Praha 6Phone: (+420 2) 2435 2503, 2435 2502, Fax: (+420 2) 2435 2500, E-mail: baumruk@fsid.cvut.cz

223 Department of Manufacturing TechnologyHead: Doc.Ing.Jan Suchánek, CSc.Address: Technická 4, 166 07 Praha 6Phone: (+420 2) 2435 2612, 311 9818, Fax: (+420 2) 2431 0292, E-mail:Jan.Suchánek@fs.cvut.cz

232 Department of Materials EngineeringHead: Prof. Ing. Josef Steidl, CSc.Address: Karlovo nám. 13, 121 35 Praha 2Phone: (+420 2) 2435 7427, 2435 7498, Fax: (+420 2) 2491 1406, E-mail: steidl@fsik.cvut.cz

238 Department of Management and EconomicsHead: Prof. Ing. František Freiberg, CSc.Address: Horská 3, 128 03 Praha 2Phone: (+420 2) 29 76 12, 2491 5319 /287, Fax: (+420 2) 29 76 12, E-mail: Frantisek.Freiberg@fs.cvut.cz

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FACULTY OF MECHANICAL ENGINEERING

STUDY PROGRAMMES

The Faculty offers 6 Bachelor Degree Programmes, 13 Master Degree Programmes and 14 Doctoral Degree (Ph.D.) programmes in the Czech language:

Bachelor Degree Programmes (Department):Transportation and Handling Technology (220)Information and Automation Technology (210)Environmental, Thermal Power and Process Engineering (207, 216, 218)Manufacturing Engineering and Management (223, 238)Production Engineering (208)Applied Mechanics (205)

Master Degree Programmes (Department):Environmental Engineering (216)Thermal and Nuclear Power Engineering (207)

Process Engineering (208)Handling and Manipulation Engineering (220)

Aerospace Engineering (220)Materials Engineering (232)Production Engineering (223)Machine Tools Equipment (208)Enterprise Management and Economics (238)

Engineering Mechanics and Mechatronics (205, 207)

Mathematical Modelling in Engineering (201)

Instrumentation and Control Engineering (210)

Biomedical and Rehabilitation Engineering (205, 210)

Doctoral Degree Programmes:Materials EngineeringMachines and Equipment for TransportationProduction Machines and EquipmentThermal Power EngineeringProcess EngineeringManufacturing TechnologyEnvironmental EngineeringBiomechanicsFine Mechanics and OpticsTechnical CyberneticsMechanics of Solids, Deformable Bodies and Continua

Thermodynamics and Fluid MechanicsMathematical and Physical EngineeringEnterprise Management and Economics

51

NOTENo bachelor programme and only one master degree program is completely available in English language. The program is Process Engineering.

Doctoral Degree Courses

Courses necessary for each specialization must be agreed with the respective supervisor at the beginning of the study.

Course Dpt. Lecturer

Partial Differential Equations 201 NeustupaNumerical methods in Aerodynamics 201 KozelComputational Mechanics of the Heat and Mass Transfer 201 VogelNumerical Solution of Ordinary Differential Equations 201 BurdaNumerical Solution of Partial Differential Equations, 201 BurdaFundamentals of Finite Elements MethodNumerical Methods in Algebra 201 NeumannováKinematical Geometry 201 KargerováDifferential Geometry 201 KargerováDifferential Geometry 201 KargerováRobotics and Geometry 201 KargerováDiffusion in Solids 202 SopkoExperimental Methods of Plasma Physics 202 NovákPhysical Measurement Methods in Engineering 202 FrankPhysical Properties of Surfaces 202 ČernýLasers and Their Applications 202 HamalSurfaces and Coatings 202 NovákRadiation Damages of Materials 202 SopkoFundamentals of Semiconductor Technology 202 SopkoGeneral English for Ph.D. Students 204 JirkůSpecialized English for Ph.D. Students 204 JirkůMechanics of Multibody Systems I. and II. 205 StejskalControlled Mechanical Systems 205 ValášekAdvanced Fluid Mechanics 207 JežekAdvanced Thermodynamics 207 NožičkaContinuum Thermodynamics 207 MaršíkGas Dynamics 207 NožičkaHeat and Mass Transfer 207 NožičkaSteam Boilers and Heat Exchangers 207 JiroušSafety of Nuclear Power Plants 207 KlikModern Power Systems 207 PetrModels in Control and Monitoring Systems 210 ZítekPrinciples of Engineering Measurements 210 KunešApplication of Artificial Intelligence in Engineering 210 BílaBasic Methods of Measurement 210 UhlířSelected Problems in Automatic Control 210 ŠulcDependability of Technical Systems 210 MykiskaAdvanced Topics in Momentum and Heat Transfer 218 RiegerMixing in Heterogeneous Systems 218 RiegerEngineering Rheology 218 ŠestákProcess Modelling and Identification 218 ŽitnýNumerical Methods in Momentum and Heat Transfer 218 ŠestákHeat and Mass Transport 218 ŠestákTurbulence in Single and Two-Phase Flows 218 Žitný

Roušar

Mathematical Modelling of Thermodynamics of Internal Combustion Engines 220 MacekPassive Safety of Vehicles 220 KovandaAerodynamics 220 BrožVortex Tubes, their Generation and Losses 220 JerieMetalworking Processes 223 ČermákCAD/CAM/CAE In Metalworking Processes 223 ČermákTheory of Corrosion and Surface Coating 223 KvasničkaMetal Forming Theory 223 ČermákExperimental Methods in Machining 223 MádlFunctional Coatings and their Applications 223 KvasničkaSurface Integrity 223 KvasničkaSurface Coating Design 223 KvasničkaMachining and Finishing Difficult to Machine Materials 223 KvasničkaOptimisation of Forming Technologies 223 ŠanovecOptimisation of Cutting Conditions 223 MádlIndustrial Logistic 223 PreclíkManufacturing Methods Improvement 223 PreclíkProcess Planning Systems 223 PreclíkTheory of Manufacturing Process and Systems Modelling 223 PreclíkTheory of Machining (Cutting 223 Mádl Selected Forming Technologies 223 Šanovec Quality Control 223 ChmelíkPhysical Metallurgy 232 Macek, ZunaMechanics of Materials 232 Janovec, CejpProcessing of Non-metallic Materials and Composites 232 Steidl, KořínekPhysics of Non-metallic Materials in Solid State 232 Steidl, KořínekExperimental Methods in Materials Science 232 Macek, SteidlMicroeconomic Theory 238 MacíkManagerial Information Systems 238 MolnárInformation Management 238 MolnárMacroeconomic Theory 238 PačesováFinancial Management 238 FreibergManagement and Cost Accounting 238 Zralý

NOTEThe above doctoral-degree courses are available for Ph.D. students exclusively.

LIST OF COURSESMASTER-DEGREE STUDY PROGRAMMES

The following list of master degree courses are subject to change.

Please check the current offer of courses on the homepage of the Faculty of Mechanical Engineering:

http://www.fsid.cvut.cz

Item EDUCATION/PROSPECTUS.

SEMESTER COURSE COURSE NoHOURS

1 Mathematics I. 201 1056 4+41 Mathematics I. - Seminar 201 6007 0+21 Constructive Geometry 201 1021 3+21 Computer Use Fundamentals I 237 2021 1+11 Chemistry 218 2019 2+11 Technical Drawing 213 2018 1+21 Fundamentals of Technology I. 233 3018 1+12 Czech Language 204 6120 0+22 Mathematics II. 201 1057 4+22 Mathematics II. - Seminar 201 6008 0+22 Physics I. 202 1024 4+22 Physics I. - Seminar 202 6003 0+22 Design I. 213 1019 1+22 Computer Graphics 201 2027 1+12 Materials Science I. 232 2029 2+12 Fundamentals of Technology II. 234 3018 1+12 CAD I. – Computers in Design 213 3011 1+22 History of Technology 213 1005 2+03 Mechanics I. 231 1101 2+23 Mathematics III. 201 1066 3+23 Algorithmization 201 2033 2+23 Materials Science II. 232 1039 2+23 Physics II. 202 1022 2+13 Physics II. – Seminar 202 1022 0+23 Design II. 213 3018 0+23 Technology II. 234 1045 2+23 Introduction into Philosophy 209 3001 0+24 Numerical Mathematics 201 1049 2+24 Mechanics II. 231 1102 2+24 Strength of Materials I. 211 1001 4+34 Thermodynamics 212 1023 3+24 Technology I. 233 1067 3+24 Mechanics II. 231 1102 2+24 Design III. 213 3019 0+24 Humanity - Information Sources 209 3271 1+15 Strength of Materials II. 211 1002 2+25 Machine Elements and Mechanisms I. 213 1010 4+25 Fluid Mechanics 212 1015 3+25 Mechanics III 231 1107 2+35 Electrical Engineering I. 214 1015 3+26 Machine Elements and Mechanisms II. 213 1026 3+06 Project I 213 2025 0+46 Economics of the Enterprise 238 1054 2+26 Momentum, Heat and Mass Transfer 218 1075 3+16 Automatic Control 237 1047 3+26 Electrical Engineering II. 214 1016 2+36 Measurement in Engineering 237 2080 2+2

Selected Courses of 7-10 Semester- must be agreed at the beginning of each semester

7 Applied Physical Chemistry 218 1028 3+27 Hydromechanical Unit Operations 218 1037 4+27 Design of Process Equipment 218 1024 4+37 Algorithms for Engineering Informatics 237 1014 2+28 Partial Differential Equations 201 1045 2+2

8 Heat Transfer Operations 218 1017 4+28 Mass Transfer Operations 218 1039 4+28 Polymer Processing 218 1091 2+28 Database and Knowledge Systems 237 1068 2+28 Dynamic System Modeling 237 1026 2+28 Instrumentation Technology in Automatic Control 237 1072 2+29 Computer Network Services 237 2015 1+29 Water Waste Treatment and Gaseous Emission Reduction218 1089 3+19 Numerical Analysis and Design of Process Equipment 218 1040 3+29 Experimental Methods 218 1068 2+29 Chemical and Bio Reactor Design 218 1077 3+29 CA Chemical Engineering Process and Management 218 1012 2+29 Process Control 218 1076 2+29 Introduction to Modelling and Simulation for Environmental Engineering 216 6007 1+39 Object Oriented Programming 237 1042 2+29 PLC in Industrial Control 237 1060 2+29 Theory of Automatic Control 237 1127 2+210 Stochastic Processes FOR engineers 237 1070 1+110 Processing Lines 218 1100 3+210 Plant Design 218 1013 2+110 Industrial Chemistry 218 1014 2+110 Capita Selecta of Modelling and Simulation for Environmental Engineering 216 6008 1+310 Computer Aided Control Design 237 1070 2+210 Theory and Methodology of Machining (Cutting) 234 1012 3+210 Manufacturing Systems Design 234 1021 2+210 Manufacturing Methods Improvement 234 2019 2+110 Theory and Methodology of Metal Forming 233 1005 3+210 Theory and Methodology of Casting 233 1008 2+2

SYLLABI OF COURSESof the first 6 semesters of Master-degree program

Code:2011021 CCONSTRUCTIVEONSTRUCTIVE G GEOMETRYEOMETRY Weekly load: 3+2Lecturer: Kargerová Study profile: all branches Assessment: a,exDepartment: 201.3 Credits: 6 Semester: 1

Course description:Projection methods (axonometry, obligue projection, linear perspective), planar kinematical geometry (trajectory, envelope, cyclic motion), helix, surfaces ( sf. of revolution, helicoidal sf., developable sf., envelope sf.).

Contents:1. Monge projection 2. Obligue projection3. Orthogonal axonometry4. Linear perspective5. Kinematical geometry6. Kinematical geometry7. Surfaces of revolution8. Surfaces of revolution9. Helix

10. Helicoidal surfaces11. Developable surfaces12. Developable surfaces13. Envelope surfaces14. Envelope surfaces

Recommended literature:1. Kargerova,M.: Geometry and Computer Graphics. CTU Publishing House, Prague, 1998

Key words: Projection, kinematical geometry, motion, curve, surface, screw motion, development

Code:2011049 NNUMERICALUMERICAL M MATHEMATICSATHEMATICS Weekly load: 2+2

Lecturer: Kolman Study profile: all branches Assessment: a, exDepartment: 201.2 Credits: 4 Semester: 4

Course description:An overview of typical mathematical problems faced by engineers that can not be solved explicitly. Numerical approaches to their approximate solutions

Contents:1. Matrices; System of linear equations – direct methods; Gauss elimination for tri-diagonal

systems; Principle of iterative methods; norms and spectral radius.2. Simple and Jacobi iterative method; Gauss-Seidel method; convergence conditions.3. Systems of nonlinear equations; Problems of existence and uniqueness of the solution;

Iterative methods – Newton method; Analogy of 1D problem.

4.Principle of interpolation; Interpolation by algebraic polynomials; Existence and uniqueness of the polynomial; Interpolation by spline functions; Advantages of this interpolation; Practical applications.

5. Least squares approximation – principle of approximation by an algebraic polynomial; Derivation of the system of normal equations;

6-8.Numerical solution of the Cauchy problem for the 1st order equation and for a system in normal form; Cauchy problem for the nth order equation; Principle of one-step methods of Euler & Runge-Kutta; Convergence; Practical application;

9-10.

The problems of the solution of the boundary value problems for an 2nd order ordinary differential equation, comparison with the Cauchy problem; Existence and uniqueness; Dirichlet problem; Principle of the mesh methods (finite difference methods), convergence; Existence and uniqueness of the solution of the associated system of linear equations; Shooting method;

11-13.

Numerical solution of the linear partial differential 2nd order equations in 2D –mesh methods; Classes of equations; Formulation of elementary problems for the equations of the mathematical physics (Laplace and Poisson equation; Heat transfer equation, Wave equation); Difference substitutions of the first and second derivative order of the approximation; Principle of the mesh method for the solution of individual types of problems; Convergence and stability;

Recommended literature:

1. Mathews, J. H.: Numerical Methods for Mathematics, Science and Engineering, Prentice Hall International, 2nd edition,1992

2. Gerald, C.F., Wheatley, P.O.: Applied Numerical Analysis, Addison Wesley, 6th edition, 1999

Key words: Numerical methods; system of equations; differential equations

Code:2011056 MMATHEMATICSATHEMATICS I I Weekly load: 4+4Lecturer: Neustupa, Study profile: all branches Assessment: a,ex

KračmarDepartment: 201.1 Credits: 8 Semester: 1

Course description: Introduction to linear algebra, calculus of functions of one variable, indefinite and definite integrals. Simple applications in physics and geometry.

Contents:

1. Linear algebra: Vector spaces. 2. Matrices and determinants.3. Systems of linear algebraic equations.4. Linear transformations of Euclidean spaces. Eigenvalues, eigevectors of square matrices.5. Differential calculus: Sequences of real numbers and their limits. 6. Function of one real variable - limits, continuity, derivatives.7. Higher order derivatives.8. Application of derivatives, behaviour of a function.9. Taylor’s polynomials, MacLaurin’s polynomials.

10. Non-linear equation for one unknown.11. Indefinite integrals: Antiderivative, indefinite integral, basic methods of integration:

integration by parts, method of substitution.12. Integration of rational and simple irrational functions, integration of trigonometric functions.13. Separable differential equations.14. Definite integral: Definition, basic properties and methods of calculation, applications.

Recommended literature:1. Neustupa, J.: Mathematics I, CTU Publishing House, Prague, 19962. Finney, R. L., Thomas, G.B.: Calculus, Addison-Wesley, New York, Ontario, Sydney, 1994

Key words: Linear algebra, differential calculus, integral calculus (indefinite and definite integral)

Code:201 1057 MMATHEMATICSATHEMATICS IIII Weekly load: 4+2Lecturer: Kračmar,

Neustupa Study profile: all branches Assessment: a, exDepartment: 201.1 Credits: 6 Semester: 2

Course description:Introduction to the calculus of functions of more variables, double and volume integrals, line and surface integrals, theory of a field. Applications in physics and in geometry. Contents:

1. Differential calculus of functions of more variables: limit, continuity, partial derivative. 2. Higher order partial derivatives.3. Maxima and minima.4. Implicit functions.5. Double integral: definition, basic properties, method of calculation (Fubini theorem.

transformation to polar and other coordinates), applications.6. Volume integral: definition, basic properties, methods of calculation (Fubini theorem,

transformation to cylindrical, spherical and other coordinates), applications.7. Line integral of a scalar function: definition, basic properties, calculation, applications. 8. Line integral of a vector function: definition, basic properties, independence on the path,

calculation.9. Green theorem, applications.

10. Surface integral of a scalar function: definition, basic properties, calculation, applications.11. Surface integral of a vector function: definition, basic properties, calculation, applications.12. Operators div and curl, Gauss theorem and Stokes theorem.13. Potential vector field.14. Solenoidal vector field.

Recommended literature:1. J. Neustupa, J., Kračmar, S.: Mathematics II, CTU Publishing House, Prague, 19982. R. L. Finney,R.L, Thomas, G.B.: Calculus, Addison-Wesley, New York, Ontario, Sydney,

1994

Key words: Multi-variable calculus, double and triple integrals, line integrals, surface integrals, theory of a field

Code:2011066 MMATHEMATICSATHEMATICS III III Weekly load: 3+2Lecturer: Burda Study profile: all branches Assessment: a,exDepartment: 201.2 Credits: 5 Semester: 3

Course description:Theory of ordinary differential equations. First and second order differential equations. Systems of differential equations in normal form. Initial value problem. Linear and nonlinear systems. Autonomous systems and their dynamic properties. Infinite series. Power series. Taylor expansion. Applications.

Contents:1. Ordinary differential equations of first order. Basic concepts. Maximal solution. Existence

and uniqueness of maximal solution of the initial value problem. 2. Separable differential equations. Homogeneous differential equations of first order. Exact

equation. Linear differential equation of first order. Bernoulli equation.3. Systems of differential equations in normal form. Fundamental set of solutions of

homogeneous linear systems. The Wronskian.4. Linear differential equations of 2-nd order. Method of undetermined coefficients.5. Autonomous systems. Dynamic interpretation in the phase space.6. Homogeneous linear autonomous systems. The Euler method for the general solution.7. Phase diagram of the homogeneous linear autonomous system in the plane. Various types

of equilibrium points. Nonhomogeneous linear autonomous systems.8. Nonlinear autonomous systems. Properties of phase trajectories. First integral.9. Infinite series of numbers. Tests of convergence for the series with positive terms.

10. Series with arbitrary real terms. Absolute and conditional convergence. The Leibnitz test. 11. Power series. Structure of the domain of convergence and determination of the domain.12. Operations on power series (multiplication, differentiation, and integration of power series).13. The expansion of a function into the Taylor/MacLaurin series.14. Application of power series to the solution of the initial value problem for the linear

differential equation of 2-nd order with variable coefficients.

Recommended literature:

1. Burda, P.: Mathematics III, Ordinary Differential Equations and Infinite Series, CTU Publishing House, Prague, 1998.

Key words: ordinary differential equations, initial value problem, autonomous systems, infinite series, power

series.

Code:2012027 CCOMPUTEROMPUTER G GRAPHICSRAPHICS Weekly load: 1+1Lecturer: Kargerová Study profile: all branches Assessment: caDepartment: 201-3 Credits: 2 Semester: 2

Course description:Modelling of curves, surfaces, solids. Algorithms and means of computer graphics (visibility, shading, colour models). Design of models using software DesignCad-3D and Maple.

Contents:

1. Modelling of solids (wire frame, CSG model, B- representation)

2. Modelling of curves (Ferguson cubics, Bezier curves)3. Composite curves, Coons B-spline4. Modelling of surfaces (Coons and Bezier patches)5. Computer rendering (algorithms of visibility)6. Light definition, Colour definition, models RGB, CMY,HLS 7. Shading, ray-tracing8.9.

10.11.12.13.14.

Recommended literature:1. Kargerova, M.: Geometry and Computer Graphics, CYU Publishing House, prague, 1998

Key words: Modelling, curves, surfaces, colour model, shading, light

Code:2012033 AALGORITHMIZATIONLGORITHMIZATION ANDAND P PROGRAMMINGROGRAMMING Weekly load: 2+2Lecturer: Kolman Study profile: all branches Assessment: caDepartment: 201.2 Credits: 4 Semester: 3

Course description:Pat I: An introduction to elementary programming, learning the basic principles, building the capacity to write gradually more and more complex programs (still very basic but writing them oneself and from scratch). Part II: Learning specific algorithms tackling simple problems from numerical mathematics as applied in engineering problems.

Contents:

1.Example of elementary program, program structure, programming process; Algorithm statements; Building blocks of C language;

2.Statements, assignment, priorities of operations; Mathematical functions, standard libraries;Flow control: Conditional statement, Switch, Goto;

3. Cycles: For, While, Do-while; Break; Continue;

4. Formatted and unformatted intput/output; Input/output from data files;

5. Functions - call by value, call by reference; Recursive functions;

6.Pointers; Array as a parameter of function; function as a parameter of function;Data types typedef, enumeration, structure;

7. Dynamic memory allocation: one-dimensional arrays, multi-dimensional arrays;8. Sorting: direct selection, bubblesort, shakesort, quicksort;9. Numerical integration: trapezoidal method, Simpson’s method;

10. Equation f(x)=0: bisection method, iterative method, Newton’s method;11. System of linear algebraic equations: Finite methods:

Gaussian elimination, Gaussian elimination for tridiagonal system;12. System of linear algebraic equations: Iterative methods:

Jacobi's method, Gauss-Seidel method;13. Cauchy problem for one ordinary differential equation

Recommended literature:1. Barclay,K.A.: ANSI C Problem Solving and Programming, Prentice Hall 1990;2. www.cplusplus.com/doc/tutorial

Key words: Algorithms, programming, C language, numerical mathematics

Code:2021022 PPHYSICSHYSICS II II Weekly load: 4+2Lecturer: Veselá Study profile: all branches Assessment: a, exDepartment: 202 Credits: 7 Semester: 3

Course description:Faraday's law of electromagnetic induction. Maxwell's equations, electromagnetic waves. Light, wave optics, geometrical optics. Quantum properties of electromagnetic waves. Interaction of radiation with matter. Photoelectric effect. Wave-particle mature of matter. Quantum-mechanical description of particle's motion. Hydrogen atom and periodic system of elements. Spectra, x-rays, ;laser. Band theory of solids, semiconductors. Nucleus, radioactivity, sources of nuclear energy. Laboratories - measurements of 6 experiments related to the lectures. Contents:

1. Faraday's law of electromagnetic induction, self-inductance, mutual inductance.2. Maxwell's equations, displacement current.3. Electromagnetic waves, interaction of radiation with matter. Light.

4. Geometrical optics.5. Wave optics, interference. Special theory of relativity.6. Particle nature of radiation. Photoelectric effect. Black-body radiation, the Compton effect.7. Wave-particle nature of matter. De Broglie waves. The Heisenberg uncertainty principle. 8. Models of hydrogen atom, quantum numbers, electron spin.9. Introduction into quantum mechanics - Schrodinger equation.

10. Particle in a box. Harmonic oscillator. Periodic system of elements. 11. Spectra, x-rays, laser. Molecular bonds. 12. Band theory of solids, semiconductors.13. Radioactivity, activity, disintegration law, half-life, sources of nuclear energy,

measurements.14. Fundamental elementary particles, classification. Cosmology.

Recommended literature:

1. Young, H.D., Freedman, R.A.: Sears and Zemansky' University Physics, 10th edition, Addison-Wesley, 2000

Key words: Electromagnetic induction, inductance, Maxwell's laws, electromagnetic waves, optics, particle

nature of radiation, wave nature of particles, models of hydrogen atom, quantum numbers, exclusion principle, uncertainty principle, periodic system of elements, Schrodinger equation, spectra, molecular bonds, band theory of solids, nuclear physics, half-life, activity, elementary particles, cosmology.

Code:2021022 PPHYSICSHYSICS I I Weekly load: 2+1Lecturer: Veselá Study profile: all branches Assessment: a, exDepartment: 202 Credits: 3 Semester: 2

Course description: Kinematics and dynamics of a particle motion. Principle of conservation of energy. System of particles, centre of mass. Rigid body. Continuum, elastic properties of bodies. Oscillations, waves. Fluid mechanics. Temperature and heat transfer. Kinetic theory of gases. Thermodynamics. Electric field, current, conductivity, resistance. Conductors, semiconductors, insulators. Magnetic field. Magnetic materials. Electromagnetic field. Laboratories - accuracy of measurements, systematic and random errors, uncertainty of direct and indirect measurements, regression, measurements of 11 various experiments related to the lectures.Contents:

1. Physical quantities - vectors and scalars. Kinematics of a particle motion in one dimension.2. Motion in two or three dimensions, circular motion. Newton's laws of motion. Galileian

transformation.3. Motion equations, applications. Dynamics of a circular motion. Work and energy. Principle of

conservation of energy. Momentum, impulse, collisions. Centre of mass. Rigid body.

Rotational and translational motions, the torque. Conservation of momentum and angular momentum.

4. Gravitation, Newton's law of universal gravitations. Potential and intensity of a gravitational filed, satellites. Fluid mechanics, surface tension.

5. Continuity equation, Bernoulli's equation. Viscosity. Temperature, heat, calorimetry. Internal energy, first law of thermodynamics.

6. Thermodynamic processes. The Carnot cycle. Equipartition of energy theorem. The second law of thermodynamics, entropy, probability, information.

7. Elasticity, stress, strain, elastic moduli. SHM, the physical pendulum, the simple pendulum, damped oscillations, forced oscillations, resonance.

8. Mechanical waves, types, mathematical description, sound, beats, the Doppler effect.9. Electric charge, electric filed, intensity. Electric flux, Gauss's law, electric potential.

10. Capacitors, capacitance, energy of electric field, Gauss' law in dielectrics.11. Electric current, resistivity, resistance, electromotive force.12. Direct-current circuits, Kirchhoff's rules, power and energy in electric circuits.13. Magnetic field, the Hall effect, magnetic materials.14. Mass spectrometer, cyclotron. Sources of magnetic filed, Ampere's law.

Recommended literature:

1. Young, H.D., Freedman, R.A.: Sears and Zemansky' University Physics, 10th edition, Addison-Wesley, 2000

2. Vesela E., Physics I, CTU Publishing House, Prague, 2003

Key words: physics, accuracy, theory of errors, kinematics, dynamics, motion equations, harmonic motion,

centre of mass, deformation, continuum, hydrodynamics, kinetic theory of matter, thermodynamics, mechanical waves, electric field, electric current, circuits, magnetic field, magnetic materials

Code:2093001 IINTRODUCTIONNTRODUCTION INTOINTO P PHILOSOPHYHILOSOPHY Weekly load: 1+1Lecturer: Zamarovský Study profile: all branches Assessment: aDepartment: 238.3 Credits: 2 Semester: 1

Course description:Brief overview of main persons and ideas of ancient philosophy. The basic aim is to point out close relation of ancient philosophical ideas with our present day problems.

Contents:1. What is philosophy, the mythological background.2. Presocratic philosophers, the Milesians and concept of arche, reductionism and science.3. Pythagoras and the Pythagoreans, metempsychosis, soul, mathematics, medicine etc.4. Heraclitus and his view on nature. Temporality and Eastern philosophy.5. The Eleatic school, problem with negative concepts and vacuum, Zeno`s paradoxes.6. The way to materialism (Empedocles, Anaxagoras).7. Atomism, Democritus and Leucippus. Ancient and modern concepts of atom, cosmology.8. Concept of ananke, absolute determinism, Laplace demon and modern science.9. The Sophists, subjectivism and relativism. Sophists and post-modern philosophy.

10. Socrates and his method. Socratic schools. Megarians and paradox of the liar.11. Plato and Platonism. Idealism, the allegory of the cave and it`s consequences. Atlantis.12. Aristotle, his live and teaching. Logic, methodology of science, Aristotelian physics.13. Philosophy of the Hellenistic period. Epicurus and atomism. Stoicism, scepticism.

14. Science in Alexandria, Archimedes, Euclides and geometry.

Recommended literature:1. Zamarovský, P.: The Roots of Western Philosophy, CTU Publishing House, Prague, 2000.2. http://www.ditext.com/encyc/frame.html

Key words: philosophy, science, history, interdisciplinarity

Code:2093271 HHUMANITYUMANITY - I - INFORMATIONNFORMATION S SOURCESOURCES Weekly load: 1+1Lecturer: Tichá Study profile: all branches Assessment: aDepartment: 12138 Credits: 2 Semester: 4

Course description:Information literacy presents the ability to recognise the information need, to locate, evaluate, and use effectively the needed information. The course concentrates on searching printed and electronic information sources for engineers, online searching strategy, library services, the internet information sources and also on references, citation and copyright principles.

Contents:1. Introduction to information literacy.2. Library catalogues 1. CTU libraries.3. Library catalogues 2. State Technical Library.4. Electronic information sources available in CTU network 1. Dialog.5. Electronic information sources available in CTU network 2. Web of Science.6. Electronic information sources available in CTU network 3. ProQuest, PCI.7. Electronic information sources available in CTU network 4. Electronic journals.8. Document delivery services.9. Searching the Internet versus searching databases.

10. Special engineering documents 1. Technical standards.11. Special engineering documents 2. Patents. Industrial Property.12. References and citations.13. Revision lesson.

14. Final report results. Evaluation and assessment.

Recommended literature:

1. Information Literacy Course. Handouts and Presentations. [online]. CTU in Prague. [cit. 22.5.2003]. Available on WWW: <http://knihovny.cvut.cz/courses/handouts.html.en>

2. TILT: Texas Information Literacy Tutorial [online]. The University of Texas System Digital Library © 1998-2002 [cit. 22.5.2003]. Available on WWW: <http://tilt.lib.utsystem.edu/>

Key words: electronic information sources, information literacy, library services, bibliographic references

writing styles

Code:2111001 SSTRENGTHTRENGTH OFOF M MATERIALSATERIALS I I Weekly load: 4+3Lecturer: Sochor Study profile: all branches Assessment: a, exDepartment: 205.1 Credits: 8 Semester: 4

Course description:This course is to provide the ability to comprehend and analyze basic types of loading of simple machine members in order to determine their stress states and deformations. This provides tools for dimensioning the members and/or determining their allowable loading. This subject also provides the prerequisite for other advanced and special courses concerning the theory of elasticity and plasticity. Seminars are devoted to practical design and computation of simple machine elements.

Contents:1. Tension and compression. 2. Trusses both statically determinate and indeterminate3. 2D- and 3D-stress state (principal stresses and planes and maximum shearing stress).4. Strain energy for multiaxial stress state.5. Theories of failure.6. Torsion of circular bars.7. Centroids, second moments of area, and products of inertia of plane areas.8. Bending of beams (shearing force, bending moment, normal and shearing stresses in

beams). 9. Deflection of beams.

10. Statically indeterminate beams.

11. Combined loading (unsymmetrical bending; bars with axial loads; bending and torsion; torsion and tension; bending and shear).

12. Design for fatigue strength (cyclic loading; S-N diagram; Smith’s and High’s fatigue diagrams)13. Safety factors for fatigue strength; stresses due to combined loading.14. Thin-walled rotational membranes.

Recommended literature:1. Sochor, M.: Strength of Materials I, CTU Publishing House, Prague, 19982. Nash, W.A.: Strength of Materials, Schaum’s outline series, 2nd edition, McGraw-Hill, INC,

1998

Key words: 2D and 3D stress state; strain energy; loading in tension, compression, bending and torsion; fatigue strength; thin-walled rotational membranes

Code:2111002 SSTRENGTHTRENGTH OFOF M MATERIALSATERIALS II II Weekly load: 2+2Lecturer: Sochor Study profile: all branches Assessment: a, exDepartment: 205.1 Credits: 5 Semester: 5

Course description:This course is to provide an advanced analysis of machine members. It also provides the prerequisite for other special courses concerning the theory of elasticity and plasticity.

.

Contents:1. Bending of curved rods.2. Bending of frameworks.3. Thick cylinders4. Compound thick cylinders5. Circular plates6. More general types of CP loading7. Buckling of columns 8. Combined stress: buckling & bending 9. 3-D stress state

10. Geometrical theory of strains 11. Torsion of bars having non-circular profiles.12. Torsion of thin-walled profiles13. Plastic limit analysis of structures14. Plastic behaviour of thick cylinders under inner overpressure

Recommended literature:1. Sochor, M.: Strength of Materials II, CTU Publishing House, Prague, 2002

2. Heam, E.J.: Mechanics of Materials II, Textbook of University of Warwik, UK, 1998

Key words: Curved rods and frames, thick cylinders, circular plates, buckling of columns, 3-D stress state,

torsion of non-circular profiles, Plastic limit analysis of structures

Code:2121015 FFLUIDLUID M MECHANICSECHANICS Weekly load: 3+2Lecturer: Adamec,Ježek Study profile: all branches Assessment: a, exDepartment: 207.1 Credits: 7 Semester: 5

Course description:The first course in Fluid Mechanics designed to provide the fundamental tools necessary to analyse a fluid systems and predict its behaviour.

Contents:1. Introduction, basic properties, quantities and units, Fluid statics, development

of the hydrostatic law2. Forces on submerged surfaces, buoyancy3. Ideal fluid in motion: basic laws – continuity equation, Bernoulli equation, linear

momentum equation, discharge from vessels, one-dimensional pipe flow4. Frictional and local losses5. Principles of pressure, velocity and discharge measurement6. Unsteady one-dimensional flow7. Relative flows8. Force action on fluid jet9. Laminar flows

10. Turbulent flows11. Flow past bodies, boundary layer, drag and lift, wing theory12. Dimensional analysis and model theory13. Potential flow theory14. Navier-Stokes equation

Recommended literature:1. White, F. M.: Fluid Mechanics, 3rd ed., New York, 1994 2.M

u

nson,B.,Young,D.,Okiishi,T.:Fundamentals of Fluid Mechanics, 2

nd

ed., New York,1994

3. Douglas, J., Mathews, R.: Solving Problems in Fluid Mechanics, Vol. 1 and 2, Longman, Malaysia, 1998

Key words: Hydrostatics, continuity energy and momentum equations, pipe flow, flow past bodies, model

theory, potential flow

Code:2121023 TTHERMODYNAMICSHERMODYNAMICS Weekly load: 3+2Lecturer: Jílek Study profile: all branches Assessment: a, exDepartment: 207.1 Credits: 5 Semester: 4

Course description:The course deal with a basic engineering approach to classical thermodynamics, heat transfer and compressible flow through nozzles and diffusers. Basic concepts and principles are introduced, and they are applied mostly to systems behaving as ideal gases or typical vapours. Basic notions associated with ideal mixtures are studied with an emphasis on psychometrics. Heat transfer covers fundamentals of conduction, convection and radiation. Heat exchangers are treated as an engineering application.

Exercises and labs are devoted to practical problems and experimental technique.

Contents:1. Basic thermodynamical concepts. 2. Basic laws of thermodynamics.3. Mathematical relations of thermodynamics. Ideal gas application.4. Processes in Ideal gases. Mixtures of ideal gases5. A general approach to irreversible processes in ideal gases. Mixing. 6. Real gases. Phase change processes. 7. Reversible and irreversible processes in vapours. Throttling.8. Psychometrics9. Heat transfer by conduction. The Fourier-Kirchhoff equation. One-dimensional stationary

cases.10. Heat transfer by convection. Overall heat transfer.11. Heat exchangers. Heat transfer by radiation.12. Equations of one-dimensional compressible flow. Speed of sound.13. Nozzles and diffusers.14. Cycles in engineering application.

Recommended literature:1. Jílek, M.: Thermomechanics, CTU Publishing House, Prague, 2002.2. Jílek: Exercises and Labs in Thermomechanics, CTU Publishing House, Prague, 2002

Key words: Energy, energy transformation, engineering cycles, laws of thermodynamics, mixtures,

psychometrics, heat transfer, conduction, convection, radiation, heat exchangers, compressible flow, nozzles, diffusers.

Code:2131010 MMACHINEACHINE E ELEMENTSLEMENTS ANDAND M MECHANISMSECHANISMS I I Weekly load: 4+2Lecturer: Jančík Study profile: all branches Assessment: a, exDepartment: 12108 Credits: 7 Semester: 5

Course description:Joints, joining elements (screwed, clamped, splined, welded, soldered, adhesive joints, feathers, pins, tenons, cotters, keys). Mechanical transmissions (gear, belt, chain and friction drives). Seminars are devoted to practical individual design projects of motion screw, preloaded connecting bolts, pressed, splined and key joints between shafts and hubs, non-detachable welded and riveted joints, belt and chain drives. Sketching of machine elements and simple assembly units is also indispensable seminar work.

Contents:1. Basic principles of supporting systems design in theory and practice.2. Bolt and screw joints. Geometry, mechanics and design of thread pairs. 3. Bolt and screw connections – theory and design of preloaded joints. 4. Design of preloaded bolts and screws at variable external load. Motion screws and nuts.5. Removable joints of shafts and hubs – clamped, pressed, keyed, splined.6. Joints with clevis pins, pins, shrunk-on rings. Design of welded joints.7. Butt and fillet welds – practical design calculations. Bonded and riveted joints.8. Mechanical transmissions – kinematic and dynamic behaviour, calculating models.9. Design of belt and chain drives, transmissions with friction wheels.

10. Geared transmissions – types, basic law of gearing, theory of involute gearing.11. Spur gear drives – dimensional and strength calculations, design, measuring, production.12. Helical gear drives – virtual gear theory, rules of calculating methods.13. Bevel gear drives – virtual and bivirtual gears theory, rules of calculating methods.14. Hypoid gear drives. Worm gear drives – dimensional and strength calculations.

Recommended literature:

1. Jančík, L.: Machine Elements and Mechanisms I, CTU Publishing House, Prague, 2002.Jančík, L.: Machine Elements and Mechanisms – Tasks (study texts), CTU, Praha, 2002

2. Shigley, J.E., Mischke, C.R.: Mechanical Engineering Design, McGraw-Hill, New York, 1989

Key words: supporting systems, mechanical joints, material joints, joining elements, mechanical

transmissions, dimensioning, loading capacity, durability, reliability.

Code:2131019 DDESIGNESIGN F FUNDAMENTALSUNDAMENTALS I I Weekly load: 1+2Lecturer: Křivý Study profile: all branches Assessment: a,exDepartment: 208.1 Credits: 3 Semester: 2

Course description: Acquirement of the fundamental knowledge of representation and dimensioning of machine elements founded in the acquaintance with the function of a part in the technical system and the function of form elements of the part. Analysis of the assembly of simple mounting units.

Contents:1. Standardization of technical documentation. Technical drawings. General rules of technical

representation. Gears, splines representation and dimensioning.2. Principal rules of dimensioning. Title block. Gradation of quantities. Choice of series of

preferred numbers3. Use of series of preferred numbers. Surface quality - formation of surface, terminology,

surface parameters.4. Amplitude parameters (Ry, Rz, Ra, Rq), spacing parameters (Sm, S), hybrid parameters

(tp, Abbot curve). Shaft and hub joints.5. Accuracy of dimensions. Terminology. ISO system of limits and fits.6. Shaft basis and hole basis systems of fits. Interchangeable system (clearance fit,

interference fit, transition fit).Analysis of a mounting unit.7. Relationship between tolerance and surface roughness. General tolerances.8. Dimensional loops. Terms and definitions. Linear dimensional loops.9. Geometrical tolerances - terms and definitions.

10. Fundamental principle of tolerances. Form, attitude, and position tolerances.11. Run out tolerances. Dependent and independent tolerances. Minimum and maximum

material principle.12. Projecting tolerance zone. General geometrical tolerances. Tolerance of angles.13. Cone joints and fits. Tolerancing of cones. Analysis of tolerancing ways.14. Tolerancing of threads.

Recommended literature:

1 Křivý, J., Pospíchal, J.: Fundamentals of Design I. Technical Drawings. Representation and Dimensioning, CTU Publishing House, Prague, 1999

2 Křivý, J.: Fundamentals of Design II. Rules of Interchange ability. Representation and Dimensioning of Machine Elements, CTU Publishing House, Prague, 1999

3 SSTANDARDTANDARD SELECTIONSELECTION

Key words: Interchangeability, representation, dimensioning, tolerances, roughness surface, preferred

numbers

Code:2131026 MMACHINEACHINE E ELEMENTSLEMENTS ANDAND M MECHANISMSECHANISMS II II Weekly load: 3+0Lecturer: Jančík Study profile: all branches Assessment: exDepartment: 208.1 Credits: 3 Semester: 6

Course description:Axles and shafts, sliding and rolling bearings, shaft connections with couplings and clutches, elements of crank mechanisms, pipelines and fittings.

Contents:1. Axles and shafts – preliminary design, strength and deformation evaluation. 2. Vibration of shafts. Sliding bearings – bases of tribology, lubricants, and materials. 3. Radial sliding bearings operating at hydrodynamic or hydrostatic lubrication.4. Design, loading capacity, durability of sliding bearings. Rolling bearings - standardisation.5. Kinematics, dynamics, loading capacity, durability of rolling bearings. Shaft supporting.6. Shaft coupling and clutches – kinematics, dynamics, characteristics, design, reliability.7. Mechanically controlled shaft clutches – design, loading capacity, compensating behaviour.

8. Special shaft clutches – safety, starting, overrunning clutches. 9. Main parts of crank mechanisms, kinematics of crank mechanism, indicator diagrams.

10. External, internal and inertial forces loading crank mechanisms.11. Loading, preliminary strength calculation and design of main parts of crank mechanisms.12. Flow of substance through pipeline - operating parameters, diameters of pipelines. 13. Pipes and fittings – materials, loading capacity, couplings, compensators.14. Survey of force calculations of closing cocks, valves and gate valves.

Recommended literature:1. Jančík, L.: Machine Elements and Mechanisms II (study texts), CTU, Prague, 2003.2. Shigley, J.E., Mischke, C.R.: Mechanical Engineering Design, McGraw Hill, New York,

1989.

Key words: axles, shafts, sliding bearings, rolling bearings, shaft couplings, shaft clutches, parts of crank

mechanisms, pipelines, fittings, dimensioning, loading capacity, durability, reliability.

Code:2132018 TTECHNICALECHNICAL D DRAWINGRAWING Weekly load: 1+2Lecturer: Křivý Study profile: all branches Assessment: caDepartment: 208.1 Credits: 2 Semester: 1

Course description:Acquirement of the fundamental knowledge of representation and dimensioning of machine elements founded in the acquaintance with the function of a part in the technical system and the function of form elements of the part. Representation and dimensioning of machine elements (sketches and drawings - according to models). Screw joints.

Contents:1. Standardization of technical documentation. 2. Technical drawings (types, scales, layout of drawing sheets, type of lines, folding of

drawings).3. General rules of technical representation. Orthographic projection. Views, sectional views,

number of views. Local, partial, cross-sections. Sketches.4. Principal rules of dimensioning. Dimension, projection, leader lines. Indicating of

dimensional values. Systems of dimensioning.5. Dimensioning of basic geometrical features. Indication of dimensional accuracy.6. Indication of semi-products - bar profiles. Title block.7. Representation and dimensioning of machine elements. Representation and dimensioning

of threads, bolts, nuts8. Inscription of limit deviations of angular dimensions. Indication of surface roughness,

surface treatment.9. Dimensioning of symmetrical subjects. Indication of geometrical tolerances.

10. Indication of form and position accuracy.11. Screw joints and locking elements.12. Drawings of parts and assemblies. Proposal drawings.13. Technical report. Bibliographic data.14. Registration of credits.

Recommended literature:

1 Křivý, J., Pospíchal, J.: Fundamentals of Design I. Technical Drawings. Representation and Dimensioning, CTU Publishing House, Prague, 1999

2 Křivý, J.: Fundamentals of Design II. Rules of Interchangeability. Representation and Dimensioning of Machine Elements, CTU Publishing House, Prague, 1999

3 SSTANDARDTANDARD SELECTIONSELECTION

Key words: technical documentation, representation, dimensioning, drawings, sketches, title block, thread, joints, locking

Code:2132025 PPROJECTROJECT I I Weekly load: 0+4Lecturer: Jančík Study profile: all branches Assessment: caDepartment: 208.1 Credits: 4 Semester: 6

Course description:Elaboration of semester main global project of mechanical drive of conveyor composed of electric motor, elastic shaft coupling (respectively V-belt drive), two-stage gearbox provided with minimally two pairs of helical mating gears (respectively one pair of bevel mating gears and one pair of helical mating gears) and compensating double-row toothed shaft coupling (respectively roller chain drive). Second, alternative arrangement of projected mechanical drive is provided instead of two-stage gearbox and additional mechanical drives by means of one single-stage warm gearbox.All the individual projected mechanical drives are composed of conception design, in detail solved design calculations, assembly drawing, subassembly drawings, detail drawings and material, technological and economical analyses in form of partial reports.

Contents:

Recommended literature:1. Jančík, L.: Design Project I (study texts), CTU Publishing House, Prague 2003.2. Jančík, L.: Machine Elements and Mechanisms – Tasks, CTU Publishing House, Prague

2002

Key words: work on an individual design project

Code:2133011 CAD ICAD I Weekly load: 1+2Lecturer: Pospíchal Study profile: all branches Assessment: aDepartment: 208.1 Credits: 2 Semester: 2

Course description:Basic concepts of 2d and 3d design in Mechanical Desktop and Inventor

Contents:1. Computer Aided Design – introduction – software, hardware2. 2d drawing – line, polyline, circle, arc, point, ellipse, coordinates systems3. 2d drawing – layers, templates, snap mode, ortho mode, tracking4. 2d drawing – modification, filters5. 2d drawing – dimensioning, tolerancing6. 2d drawing – assembly drawing – dBases of standards parts7. 3d design – basic, Booleans operators8. 3d design – parametric sketches9. 3d design – constraining sketches

10. 3d design – creating sketched features11. 3d design – creating work features12. 3d design – creating placed features13. 3d design – creating drawing views 14. Test

Recommended literature:

1.Bečka, J.: CAD, CTU Publishing House, Prague, 2003Autodesk: Mechanical Desktop - TutorialsAutodesk: Inventor - Tutorials

Key words: CAD, 3d design, computer design

Code:2133018 DDESIGNESIGN II II Weekly load: 0+2Lecturer: Křivý Study profile: all branches Assessment: aDepartment: 208.1 Credits: 2 Semester: 3

Course description: Acquirement of the fundamental knowledge concerning the synthetical activity in the period of design processes of a subject especially within analysis of the function and the geometrical accuracy. Utilization of a computer add (Autocad, Pro Engineer).

Contents:1. Assignment of a mounting unit. General requirements for the arrangement of working

documentation.2. Explanation of the technical, economical aspects of the valve project in point of view of

design and technology.3. Choice of elements according to pressure, temperature and physical properties of the

floating substance.4. Working on the proposal drawing.5.6.7. Test of the proposal drawing.8. Working on the working drawings of not standard parts..9.

10. Working on the assembly drawing and item list.11.12. Technical report including choice of elements, calculations of fits, dimensional loops and

presentation of literature sources.13. Handing over of the project, checking and correction.14. Credit registration.

Recommended literature:

1 Křivý, J., Pospíchal, J.: Fundamentals of Design I. Technical Drawings. Representation and Dimensioning, CTU Publishing House, Prague, 1999

2 Křivý, J.: Fundamentals of Design II. Rules of Interchangeability. Representation and Dimensioning of Machine Elements, CTU Publishing House, Prague, 1999

3 SSTANDARDTANDARD SELECTIONSELECTION4. Catalogues of valve and piping products.

Key words: Valve, piping, pressure, temperature, floating substance, motion thread, drawing, analysis

Code:2133019 DDESIGNESIGN III III Weekly load: 0+2Lecturer: Křivý Study profile: all branches Assessment: aDepartment: 208.1 Credits: 2 Semester: 4

Course description:Acquisition of common knowledge of a technical object design processes using standard components and modulus. Reconstruction of a mounting unit.Acquirement of the fundamental knowledge concerning the synthetical activity in the period of design processes of an object especially within analysis of the function, geometrical accuracy and manufacturing technology. Utilization of a computer add (AutoCAD, Pro Engineer).

Contents:

1.General principles of a new technical product design. Instructions for the completion of the task, literature, time-table, design procedure of a given technical object,welding, documentation, weld indication. Assignment of a work piece specified for drilling jig design

2. Explanation of the technical, economical aspects of the drilling jig project in point of view of design and manufacturing technology.

3.Free-hand sketch of 3 variants – each minimal in two associated views [sectional views] - at least one solution for a multiple jig [used for more work pieces clamped simultaneously], evaluation and choice of solution.

4.5. Proposal drawing of the chosen solution.6. dtto7. dtto8. dtto

9. Test of the proposal drawing10. Drawings of not standard parts [working drawings], assembly drawing, item list,

technical report, list of used literature.11. dtto12. dtto13. Handing over of the project, corrections.14. AASSESSMENTSSESSMENT – – CREDITCREDIT REGISTRATIONREGISTRATION..

Recommended literature:

1 Křivý, J., Pospíchal, J.: Fundamentals of Design I. Technical Drawings. Representation and Dimensioning, CTU Publishing House, Prague, 1999

2 Křivý, J.: Fundamentals of Design II. Rules of Interchange ability. Representation and Dimensioning of Machine Elements, CTU Publishing House, Prague, 1999

3 SSTANDARDTANDARD SELECTIONSELECTION4. Catalogues of mechanical and hydraulic jig elements.

Key words: drilling, jig, technology, design, workpiece, interchangeability

Code:2141015 EELECTRICALLECTRICAL E ENGINEERINGNGINEERING I I Weekly load: 3+2Lecturer: Chyský Study profile: all branches Assessment: a, exDepartment: 210.1 Credits: 4 Semester: 5

Course description:Introduction into theory of electric circuits, analysis special types of electric circuits as DC and AC. Transient states in circuits with accumulators of energy. Using Symbolic-Complex method and Fourier transformation for analysis AC circuits supplied with harmonic signal. Introduction into electronics. Principle and typical parameters of basic semiconductor components. Application in electronic circuits. Analogue and digital circuits. Principle of analogue and digital signal processing.

Contents:1. Components of electrical circuits – resistors, capacitors, inductors, source of voltage and

current. Ideal, real, equivalent diagrams 2. Analysis methods of electrical circuits – Nodal voltages, loop currents, Thevenins & Nortons

theorem, principle of superposition.3. General methods for analysis of circuits with non DC supplying. Transient states.4. Symbolic-complex method and Fourier transformation for analyse of AC circuits.5. Three phase system. Electrical power in DC, AC (one and three phase) circuits.

Measurement of electrical power.6. Electronics. Diodes, rectifiers. Zener’s diode, voltage stabiliser7. Thyristor, triac, controlled rectifier, chopper8. Transistors unipolar, bipolar, linearization of transistor models.9. Transistor as amplifier.

10. Operational amplifier, inverter, integrator, digital to analogue converter11. Base of digital signals. Transistor as switch. Logical circuits. Converters of signal levels.12. Digital TTL and CMOS integrated circuits. Applications13. Microcomputer, basic structure, properties.14. Power electronics

Recommended literature:

1. Rizzoni, G.: Principles and Applications of Electrical Engineering, McGraw-Hill, 2000, ISBN 0-07-117727-2

Key words: Circuit analysis, symbolic-complex method, electrical power, semiconductors, diode, transistor

Code:2141016 EELECTRICALLECTRICAL E ENGINEERINGNGINEERING II II Weekly load: 2+3Lecturer: Chyský Study profile: all branches Assessment: a,exDepartment: 210.1 Credits: 5 Semester: 6

Course description:Fundamentals of electrical machines. Electromagnets. Transformers. Induction motors. Synchronous machines. Stepper machines. DC motors and generators. Universal motors. Electrical instruments. Distribution system of electrical energy.

Contents:1. Magnetic materials and magnetic circuits 2. DC and AC electromagnets, calculation of force and torque on electromagnet3. Transformer, principle, theory. Equivalent diagram. Phasor diagrams. No-load and short

circuit transformer.4. Transformer under load. Loses and efficiency. Special types of transformers – measuring

transformer (I, V), welding transformer. Design of instruments transformer5. Three phases transformers, magnetic circuit, connection delta, star, delta-star, Clock angle.

Parallel work of transformers6. Fundamentals of induction machines. Rotating magnetic field. Synchronous speed.7. Theory asynchronous machines. Motor and generator. Equivalent diagram. Loses in AM and

their division. Slip. 8. Kloss formula, torque diagram, Construction of AM, types of armature. 1 phase and 3 phase

motor9. Running up AM, speed control, braking. Frequency converter.

10. Synchronous machine. Motor generator. Stepper motor.11. Fundamentals of DC machines. Principle. Basic equation describing behaviour of DC

machine. Equivalent diagram.12. DC machine with separate, parallel and serial excitation. Torque characteristics.

Applications.13. Speed control of DC machines. Ward Leonard group. Universal motors.14. Distribution of electrical energy. Low voltage instruments. Fuses, breakers, contactors,

switches.

Recommended literature:

1. Roadstrum, W.H., Wolaver, D.H.: i, John Wiley & Sons, Inc., 1994, ISBN 0-471-51043-2

Key words: Electrical machines, induction motor and generator, DC machine, synchronous machine, speed

control, electrical instruments.

Code:2181075 MMOMENTUMOMENTUM, H, HEATEAT ANDAND M MASSASS T TRANSFERRANSFER Weekly load: 3+1Lecturer: Šesták Study profile: all branches Assessment: a,exInstitute: 218 Credits: 4 Semester: 6

Course description:

Based on analogies, existing between flow of real fluids, heat and mass transfer, the course deals with formulation and use of laws and interrelationships valid for all the three transport phenomena in general. Resulting scientific knowledge is applicable while designing, sizing or rating mechanical and process engineering components or systems in which flow of Newtonian as well as non-Newtonian fluids, heat and mass transfer in single or multicomponent media takes place. The course is preceded with an introduction into the fundamentals of tensor calculus in Cartesian coordinates.

Contents:1. Fundamental concepts of momentum, heat and mass transfer. Newton´s, Fourier´s and Fick

´s law. Balance of a general physical quantity in a moving continuum2. Mass and momentum balances in flowing homogeneous fluids, Cauchy´s equation. Mass

conservation equation, momentum and angular momentum balances. Constitutive equations of fluids.

3. Navier – Stokes equations of motion, exact and approximate solutions in the creeping and laminar flow regimes. Rheological constitutive equations and flow of non-Newtonian fluids

4. Momentum transfer in turbulent flow. Velocity distributions for turbulent flows in simple geometries.

5. Differential and macroscopic mechanical energy balances.6. Residence time distribution (RTD) in continuous flow systems. Basic distribution functions

with applications7. Balances in thermodynamic systems. Internal energy balance, heat transfer mechanisms,

Fourier – Kirchhoff´s energy balance.8. Conductive heat transfer. Steady and unsteady temperature distributions in solids.9. Convective heat transfer. Forced and natural convection with flow in ducts and around

objects immersed in a flowing fluid. Convective heat transfer correlations10. Heat transfer with phase changes. Boiling, condensation, melting and solidification.11. Radiation heat transfer. Radiation between black and non-black bodies. Radiant energy

transport in gases. Combined convection and radiation.

12. Mass transfer fundamentals. Concentrations, constitutive equations of molecular mass transfer, Fick´s laws.

13. Mass transfer by molecular diffusion. Diffusion through a stagnant gas film. Equimolar counter diffusion. Diffusion in solids, diffusion with chemical reactions and unsteady molecular diffusion.

14. Convective mass transfer. Analogy between heat and mass transfer. Simultaneous heat and mass transfer.

Recommended literature:1. Bird, R.B.,Stewart, W.E.,Lightfoot, E.N.: Transport phenomena, 2nd Ed.,Wiley, N.Y. 20022.Welty, J.R.,Wicks, C.E.,Wilson, R.E.: i, 4th Ed.,Wiley, N.Y., 2000

Key words: transport phenomena, momentum heat and mass transfer, Newtonian and non-Newtonian

fluids, transport properties, mechanical and process engineering equipment design.

Code:218 2019 CCHEMISTRYHEMISTRY Weekly load: 2+1Lecturer: Žitný Study profile: all branches Assessment: caDepartment: 218 Credits: 3 Semester: 1

Course description:General chemistry from the point of view of mechanical and process engineering. Physical chemistry forms 2/3 of the course (structure and properties of matter, thermodynamics, phase equilibrium, chemical reactions, reaction engineering), the remaining 1/3 is devoted to organic chemistry (hydrocarbons, polymers) and biochemistry. Laboratory practice is oriented upon the material properties measurement.

Contents:1. Classification of games and mathematical models. 2. Scope and classification of chemistry3. Matter, properties, units. Structure of matter (periodical table, notation) and bonding.4. Mass balancing, stochiometry of chemical reactions.5. State variables p,v,T, state equations (ideal gas, Van der Waals, Redlich Kwong).6. Heat and energies, internal and total energy, enthalpy in phase and chemical changes.7. First and second law of thermodynamics, entropy, Gibbs energy. Examples of industrial

processes energy balancing (feasibility of chemical reactions)8. Phase equilibrium in one-component systems – phase diagrams.9. Equilibrium in multicomponent systems (Raoult’s law, Henry’s law, phase diagrams).

10. Chemical reactions classification. Rate of chemical reactions (reaction mechanisms, reaction order, Arrhenius equation, catalysis). Equilibrium of chemical reactions.

11. Reaction engineering, batch and continuous reactors, residence time distribution, conversion in segregated and maximum mixedness flows.

12. Organic chemistry (hydrocarbons, polymers, properties of plasts)13. Biochemistry (proteins, carbohydrates, lipids, nucleotides). 14.BBio-reactions, bio and food engineering.

Recommended literature:1. Žitný, R., Krýsa, J.: Chemistry, Introductory Course. CTU Publishing House, Prague 19982. http://www.fsid.cvut.cz/cz/u218/pedagog/predmety/1rocnik/chemaj/bookchem.htm

Key words: physical chemistry, phase equilibrium, reaction engineering, organic chemistry, bio-chemistry

Code:2311101 MMECHANICSECHANICS I I Weekly load: 2+2Lecturer: Šika Study profile: all branches Assessment: a,exDepartment: 205.2 Credits: 4 Semester: 3

Course description: Mechanics I deals with the basic concepts of statics and kinematics. There are described the methods of solution of equilibrium of particles and rigid bodies and their systems with and without friction. There are introduced the methods of description of position and motion of particles and rigid bodies. Contents:

1. Introduction. Modelling. Force. Constraints of particle. Free-body diagram. Equilibrium of particle.

2. Moment of the force. Couple of forces. Constraints of rigid body in plane.3. Constraints of rigid body in space. Free-body diagram. Equivalent system of forces.

Equilibrium of rigid body.4. Statically determinate and indeterminate cases. Structural theory of system of bodies.5. Analytical solution of statical equilibrium of system of bodies. 6. Centre of mass. Internal forces.7. Mechanical work. Trusses.8. Friction. Self-locking cases. 9. Constraints with friction. Statical solution of systems of bodies with friction.

10. Kinematics of particles.11. Description of a particle position in vector and matrix formulation.12. Description of a particle motion in vector and matrix formulation.13. Kinematics of simultaneous motions. Matrix formulation.14. Concluding examples.

Recommended literature:1. Beer, F.P., Johnston, E.R.: Vector mechanics for engineers, McGraw-Hill Boston, 1998 2. http://mech.fsik.cvut.cz

Key words: Mechanics, statics, kinematics, particle, rigid body, force, friction, constraint, moment, velocity,

acceleration, matrix

Code:2311102 MMECHANICSECHANICS II II Weekly load: 2+2Lecturer: Study profile: all branches Assessment: a, exDepartment: 205.2 Credits: 4 Semester: 4

Course description:Mechanics II deals with the basic concepts of kinematics and dynamics. There are described the methods of solution of kinematics of system of bodies. There are introduced the principles for solution of dynamics of rigid bodies. There are described the methods of solution of dynamics of system of bodies in plane. There are described the basic concepts of vibration of mechanical systems.

Contents:1. Translational and rotational motion. 2. General planar motion.3. Spherical and general spatial motion.4. Analytical solution of kinematics of system of rigid bodies.5. Vector method. Elements of theory of gearing.6. Kinematical solution of system with constant ratio.7. Dynamics of system of particles.8. Dynamics of rigid body. Moments of inertia.9. Balancing of rotating rigid body. Newton-Euler equations.

10. Dynamic solution of system of rigid bodies in plane.11. Vibration of mechanical system with 1 DOF.12. Forced vibration. Accelerometer, vibrometer. Critical revolutions.13. Vibration of mechanical system with 2 DOFs.14. Concluding examples.

Recommended literature:1. Beer, F.P., Johnston, E.R.: Vector mechanics for engineers, McGraw-Hill Boston., 19982. http://mech.fsik.cvut.cz

Key words: Mechanics, kinematics, dynamics, vector method, moment of inertia, linear momentum, moment of linear momentum, Newton-Euler equations, vibration, natural frequency.

Code:2311103 MMECHANICSECHANICS III III Weekly load: 2+3Lecturer: Study profile: all branches Assessment: a, exDepartment: 1205 Credits: 5 Semester: 5

Course description:Mechanics III deals with the basic concepts of analytical mechanics. There are introduced the methods of synthesis of mechanical systems. The further special cases of mechanical systems are analysed such as cables, cams, gyroscopes. Further cases of mechanical vibrations are analysed such as bending, torsion, vibration absorption.

Contents:1. Principle of virtual work. 2. Application of principle of virtual work.3. Equilibrium position and its stability.4. Analytical solution of kinematics by matrix method.5. Graphical methods in statics and kinematics.6. Cables.7. Cams.8. Synthesis of mechanical systems.9. Lagrange equations of second kind.

10. Gyroscopes.11. Elementary theory of impacts.12. Bending and torsional vibrations.13. Vibration of mechanical system with more DOFs.14. Concluding examples.

Recommended literature:1. Beer, F.P., Johnston, E.R.: Vector mechanics for engineers, McGraw-Hill Boston, 19982. http://mech.fsik.cvut.cz

Key words: Mechanics, statics, kinematics, dynamics, principle of virtual work, Lagrange equation of second

kind, cables, cams, gyroscopes, synthesis, impact, bending vibration, torsion vibration.

Code:2321039 MMATERIALSATERIALS S SCIENCECIENCE II II Weekly load: 2+2Lecturer: Steidl Study profile: all branches Assessment: a,exDepartment: 232 Credits: 4 Semester: 3

Course description:Theory of heat treatment of steels. Heat treatment, thermodynamic and thermo-chemical treatment. Structural steels and alloys. Corrosion and stainless materials. Creep, relaxation and heat-resisting materials. Wear and wear-resisting materials. Tool steels and materials. Cast iron. Non-ferrous metals and alloys. Polymers, composites, ceramics and their modification. Laboratories.

Contents:1. Fundamentals of metallurgy of iron alloys. 2. Phase transformations in iron alloys.3. Time–temperature-transformation diagrams (isothermal and anisothermal).4. Heat treatment of iron alloys. 5. Thermo–chemical and thermo-mechanical treatment of alloys.6. Carbon and low-alloyed structural steels. 7. High-alloyed structural steels (stainless, creep-resisting, etc.).8. Steels and other materials for tools.9. Cast steels and cast irons.

10. Selected nonferrous alloys and their treatment.11. Powder metallurgy and its application.12. Plastics and their processing.13. Technical ceramics and its processing.14. Composite materials (survey of technologies and properties).

Recommended literature:1. Callister, W.D.: Materials Science and Engineering, 3rd ed.,John Wiley&Sons, Inc.,1994.2. Macek, K.- Zuna, P.: Materials Science, I.st.ed.CTU, CTU Publishing House, Prague, 1996

(in Czech)

Key words: iron alloys, phase transformations, heat treatment, steels, cast steels, cast irons, nonferrous alloys, plastics, ceramics, composite materials.

Code:2322029 MMATERIALSATERIALS S SCIENCECIENCE I I Weekly load: 2+1Lecturer: Steidl Study profile: all branches Assessment: caDepartment: 232 Credits: 3 Semester: 2

Course description:Review of engineering materials with respect to standards. Internal structure of materials. Deformation and fracture behaviour during different load conditions. Dehardening processes in metals. Mechanical and technological properties and their testing. Thermodynamic background of metallic systems. Technical ferrous alloys: steels, cast irons. Influence of chemical composition and metallurgical processes on steel grade.

Contents:

1. Introduction (history, future development, economical and ecological aspects, importance of the subject).

2. Crystal lattice and its imperfections.3. Stress and strain.4. Failure and fracture, fracture mechanics.5. Mechanical properties and their testing.6. Technological properties and macroscopic defects.7. Physical and chemical properties.8. Basic thermodynamical concepts and laws.9. Transport of heat and mass.

10. Phases and phase transformations.11. Binary equilibrium diagrams of metallic and ceramic systems.12. Selected ternary equilibrium diagrams.13. Iron-carbon alloys (stable and metastable systems of Fe-C).14. Influence of further elements on properties of iron alloys.

Recommended literature:1. Callister, W.D.: Materials Science and Engineering, 3rd ed.,John Wiley&Sons, Inc.,1994.2. Macek, K.- Zuna, P.: Materials Science, I.st.ed.CTU, CTU Publishing House, Prague, 1996

(in Czech)

Key words: crystal lattice, stress, strain, fracture, properties, thermodynamical concepts, equilibrium

diagrams, iron-carbon alloys.

Code:2331067 TTECHNOLOGYECHNOLOGY I I Weekly load: 3+2Lecturer: Král Study profile: all branches Assessment: a,exDepartment: 223.1 Credits: 5 Semester: 3

Course description:The initial stages of production are decisive for the properties of the final product. The course describes the methods of production of castings, forgings, stamped parts, and fabrication of plastics. Surface coating methods are also included. The lectures deal with the basic theory of the processes, case studies and testing methods are the subject of seminars and labs.

Contents:1. Manufacturing of semiproducts, economic aspects.2. Casting, properties and structure of materials for casting, solidification.3. Risers, gating systems design, sand casting methods.4. Permanent mould casting, design of castings, foundry equipment.5. Introduction to the theory of metal forming.6. Bulk metal forming methods. Heating for forging. Powder forging.7. Hammers and presses, energy, force, velocity. Design of forgings.8. Sheet metal forming methods. Formability criteria. Calculation of forces.9. Metal forming dies, selection of equipment, feeding devices.

10. Fabrication of plastics, compression moulding, injection moulding, thermoforming.11. Welding methods and weldability, fusion welding and pressure welding.12. Structural changes in welds, HAZ, shielding, physical welding methods.13. Design for welding, brazing and soldering.14. Surface coating methods.

Recommended literature:

1. DeGarmo, P., Black, T., Kohser, R.: Materials and Processes in Manufacturing, Macmillan Publishing Company, NJ, 1988

2. Král, M., Bednář, B., Čermák, J.: Engineering Technology, CTU Publishing House, Prague, 2003

Key words: sand casting, die casting, forging, sheet metal, welding, plastics, surface coating

Code:2333018 FFUNDAMENTALSUNDAMENTALS OFOF T TECHNOLOGYECHNOLOGY I I Weekly load: 1+1Lecturer: Král Study profile: all branches Assessment: aDepartment: 223.1 Credits: 1 Semester: 1

Course description: The students of mechanical engineering should be familiar with the basic methods of production of machine parts. The course deals with the basic methods of the manufacturing of semiproducts during the lectures. The students receive a brief practical training in the laboratories and workshops.

Contents:1. The branches of technology, introduction to properties of metallic materials.2. The production of casting in sand moulds.3. Patterns for castings, design, materials and production - laboratory.4. Permanent mould casting.5. Preparing a sand mould - workshop practise.6. Metal forming, basic methods of rolling and forging.7. hammers and presses - workshop instruction.8. Sheet metal forming, methods and equipment.9. Sheet metal forming dies and machine tools - workshop instruction.

10. Welding, types of welds, properties of welded parts, welding methods.11. Welding equipment in the workshop and laboratories.12. Introduction to surface coating methods.13. Manual arc welding - workshop practice.14. Final test.

Recommended literature:1. Rao, P.N.: Manufacturing Technology, MCGraw-Hill, New Delhi, 19922. Král, M., Bednář, B., Čermák, J.: Engineering Technology, CTU Publishing House, Prague,

1998

Key words: manufacturing, casting, welding, forging, sheet metal

Code:2341045 TTECHNOLOGYECHNOLOGY II II Weekly load: 2+2Lecturer: Mádl Study profile: all branches Assessment: a, exDepartment: 223.2 Credits: 4 Semester: 4

Course description:Theoretical fundamentals of cutting processes. Cutting tools. Cutting fluids. Economic of machining. The shapes produces, common tolerances and surface finish obtained in the following processes: Broaching, thread machining, machining of gears, superfinishing, honing, lapping. Fixed and flexible automation, NC and CNC machining, Non-conventional material removal processes.

Contents:1. Introduction. 2. Theoretical fundamentals of machining.3. Tool materials.4. Machinability.5. Cutting fluids.6. Vibrations in machining.7. Economics of machining.8. Broaching.9. Thread machining.

10. Machining of gears.11. Superfinishing Honing, Lapping.12. Fixed automation.13. Flexible automation, NC machining.14. Non-conventional machining

Recommended literature:

1. Mádl, J.: Mechanical Technology, Material-Removal processes, CTU Publishing House, Prague, 1996.

2. Degarmo, E.P., Black, J.T., Kohsedr, R.A.: Material and Processes in Manufacturing. Prentice Hall, Upper Saddle River, 1997

3. Kalpakjian, S.: Manufacturing and Technology, Production engineering, Addison-Wesley Publishing Company, USA, 1989

Key words: Machining, material removal processes, cutting processes, non-conventional processes, CNC

machining.

Code:2343018 MMANUFACTURINGANUFACTURING T TECHNOLOGYECHNOLOGY F FUNDAMENTALSUNDAMENTALS IIII Weekly load: 1+1

Lecturer: Kvasnička Study profile: all branches Assessment: aDepartment: 223.2 Credits: 1 Semester: 2

Course description:Introduction to machining. International standardization and terminology for units, their definition and symbols used in machining. Nomenclature and definitions of cutting tools. Six basic machining operations. The shapes produces, common tolerances and surface finish obtained. Important calculation methods for determination of process variables. Labs complete metrology and workshop skills.

Contents:1. Material removal processes basic information. 2. Nomenclature of surfaces, motions, geometry and kinematics quantities .3. The cut and its dimensions, forces and torques, energy and power according to ISO and SI

standards.4. Nomenclature of cutting tools. Reference systems.5. Cutting tools definitions and materials.6. Determination of the geometrical position of the cutting edge.7. Basic terminology, symbols and units in machining.8. Turning (process schematics, tools, geometry produce, tolerances and surface finish

obtained).9. Drilling.

10. Shaping and planing.11. Milling.12. Sawing.13. Grinding.14. Calculation method for estimation of main process conditions and time.

Recommended literature:

1. Boothroyd, G., Knight, Winston, A.: Fundamentals of Machining and Machine Tolls. 2nd ed. Marcel Dekker, Inc., New York and Barel. 1989. ISBN 0-8247-7852-9

Key words: Machining, international terminology, cutting tools, basic machining processes

Code:2371047 AAUTOMATICUTOMATIC C CONTROLONTROL Weekly load: 3+2Lecturer: Klán Study profile: all branches Assessment: a,exDepartment: 210.3 Credits: 5 Semester: 6

Course description:Automatic controllers are important part of many industrial processes. The goal of this course is to introduce students into basic knowledge of automatic control theory and practice like transfer functions, open versus closed loop control, design of controllers and frequency based analysis of control systems. The course also concentrates on logic control and control via programmable logic controllers. Some seminaries are arranged in laboratories where practical skills and control engineering methods are trained. Students begin to work with MATLAB software as a common platform of control engineers.

Contents:

1. Essential Principles of Automatic Control, Signals and Systems.2. Digital Logic Control.3. Combinatorial Logic Circuits and Controllers.4. Programmable Logic Controllers, Sequential Logic Circuits.

5. Continuous Linear Systems, Laplace Transform. 6. Transfer Functions, Mathematical Models, Poles and Zeros.

7. Transient and Steady State Response Analysis.8. Detailed Analysis of Selected Processes.9. Open Loop and Closed Loop Control.

10. Design of Proportional, Integral and Derivative Controllers (PID). 11. Advanced PID Controllers.12. Discrete-time based PID Controllers.13. Frequency-Response Analysis.14. Modelling Control Systems via MATLAB.

Recommended literature:1. Ogata, K.: Modern Control Engineering (4th Edition), Prentice Hall, 2001.2. Dunning, G.: Introduction to Programmable Logic Controllers (2nd Edition). Delmar Learning, 2001.3. Dorf, R.C., Bishop R.H.: Modern Control Systems (8th Edition). Addison-Wesley, 1998.

Key words: Automatic Control, Linear Dynamic Systems, PID Controllers, PLC systems, Transient and

Frequency Analysis, Design of Control Processes.

Code:237 2021 CCOMPUTEROMPUTER U USESE F FUNDAMENTALSUNDAMENTALS I I Weekly load: 1+1Lecturer: Klán Study profile: all branches Assessment: caDepartment: 210.3 Credits: 3 Semester: 1

Course description:The goal is to introduce students into problem how to create technical or professional documents on computers or Web and how to realize technical computations with using computers. The students get practical skills via creating own essay in a text editor, realizing technical computations in a spreadsheet and creating own technical-based WWW page.

Contents:1. Basic work with text editors. 2. Working with editor of mathematical formulas and their introduction into documents.3. Making final version of the technical essay.4. Introduction to technical and scientific computations via computers.5. Solving some technical problems via spreadsheets.6. Making final version of the technical-based project with graphs and computations.7. Introduction into WWW, key information WWW resources.8. Searching of technical information in electronic documents.9. Introduction to publishing on WWW.

10. Basic tags in creating WWW pages.11. Advanced tags in creating WWW pages.12. Creating of basic WWW documents.13. Making final version of the WWW page.14. Checking tasks and assessment.

Recommended literature:1. Acklen, L.: Teach yourself Microsoft Office 2000, Sams, 1999.2. Boumphrey, L. and the others: Beginning XHTML, Wrox 2000.

Key words: professional documents, technical computations, creating and publishing of WWW pages, using

computers.

Code:237 2080 EENGINEERINGNGINEERING M MEASUREMENTSEASUREMENTS Weekly load: 2+2Lecturer: Volf Study profile: all branches Assessment: caDepartment: 210.1 Credits: 4 Semester: 6

Course description:Static and dynamic properties of measurement instruments. Organisation of

measurement chain. Measurement errors, they sources and correction. Summary of principles, sensors and transducers to measurement of physical status values (temperature, position, distance, force, pressure, speed, acceleration, torque, flow, warm, humidity, level elevation, liquid and gas analysis, visual, tactile and proximity sensors). Scanning and processing measuring data. Remote measurement, signal types for data transfer, automation measurement and information systems, processing of measuring values by computer. Calibration and verification of measurement instruments.

Contents:1. Measurement system, Static characteristics of transducers. Accuracy and sensitivity of

transducers and instruments. Uncertainty of measurements.

2.Dynamic properties of sensors and transducers. Time constant of transducer and its determination and using. Possibilities transducer errors decreasing. Information transducers properties.

3. Electronic processing circles, discresation analog signals, digital signal filtration, signal modulation.

4. Temperature transducers - resistive, semiconductive, thermoelectric, pyroelectric, piezoelectric and liquid sensors.

5. Measurement of thermal power and heat, humidity measurement.6. Pressure transducers - inductive, resistive, capacitive and piezoresistive sensors7. Level elevation measurement.8. Position and distance transducers - absolute, incremental and impulse sensors, inductive,

resistive, capacitive sensors. Proximity transducers.9. Force and torque measurement - inductive, resistive, capacitive and piezoresistive sensors.

10. Tactile transducers and visual transducers - CCD, PSD elements.11. Flow measurement - electrical anemometers (resistive), mechanical (float, propeller),

Prandtl’s tube.12. Liquid and gas analysis measurement - viscosity, density.13. Turn speed, speed and acceleration measurement - mechanical, impulse, inductive,

resistive, capacitive and semicoductive sensors.14. Industry measurement systems.

Recommended literature:

1.Sedláček, M., Haasz, V.: Electrical Measurements and Instrumentation, CTU Publishing

House, Prague, 2000

2.Sirohi, R., S., Radha Krishna, H., C.: Mechanical Measurements. New Delhi, Wiley Eastern

Ltd., 1991

Ott, Soren: Measurements of Temperatures, Radiation and Heat Transfer in Natural Gas Flames: Final report JIVE project. Roskilde, Riso nat. Lab., 1993

4 Webster, J.,G.: i. Boca Raton, CRC Press 2000

5 Doebelin, E., O.: Measurement System: Application and Design. New York, McGraw-Hill, 1990

Key words: Technical measurement, sensors, transducers.

Code:2381054 EECONOMICSCONOMICS OFOF THETHE E ENTERPRISENTERPRISE Weekly load: 2+2Lecturer: Kavan Study profile: all branches Assessment: a,exDepartment: 238.1 Credits: 4 Semester: 6

Course description:The programme consists of: Management of Change and Economics, Forecasting and Operations Strategy, Design of Work Systems, Total Quality Management and Inventory Control, Material Requirements Planning and Just-In-Time Systems, Logistics and Practical exercises. The study programme has a strong international orientation. The teaching goal is to prepare students for dealing with real-world settings and implementing the most effective up-to-date practices. We aspire to lead in research, and in developing modern concepts and tools.

Contents:1. Engineering Economy for Engineering Managers. 2. Cost-Profit-Volume or Break-Even Analysis.3. Market-Related Factors.4. Overview of Forecasting Methods, Demonstration Problems.5. Decision Making.6. Japanese Influence on Operations Management.7. Facility Location and Job Design.8. Planning for Operations and Capacity.9. Inventory Management and Purchasing.

10. Material Requirements Planning.11. Just-in-Time Manufacturing Excellence. The Kanban System.12. Total Quality Management.13. Project Management, Network Techniques.14. Optimal strategy control.

Recommended literature:1. Kavan, M.: Management Study Guide, ČVUT, Praha, 1999.2. Gönen, T.: Engineering Economy for Engineering Managers, Wiley, Sacramento, 1990.3. Dilworth, J.B.: Operations Management, Mc Graw-Hill, 1992.