Bachelor of Civil Engineering (BSc program) · Bachelor of Civil Engineering (BSc program) ... Result of the final examination is determined by the arithmetic mean of the marks given

Bulletin

Bachelor of Civil Engineering

(BSc program)

University of Debrecen Faculty of Engineering

Department of Civil Engineering

2016

CONTENTS

Civil Engineering, BSc Program .................................................................................................................................. 3

Model Curriculum ................................................................................................... Hiba! A könyvjelző nem létezik.

Basic Science Subjects ................................................................................................................................................. 7

Economics and Humanities Subjects .......................................................................................................................... 12

Specific compulsory subjects ..................................................................................................................................... 16

Subjects of Structural Architect Specification ............................................................................................................ 34

FACULTY BACKGROUND, AND HISTORICAL FACTS .................................................................................... 39

FACILITIES AND INFRASTUCTURE OF THE TRAINING ................................................................................. 40

LABORATORIES ...................................................................................................................................................... 41

CONTACT INFORMATION .................................................................................................................................... 60

3

Civil Engineering, BSc Program

The aim of the teaching is to train professionals, having a civil engineering degree, who are are

intrigued by technologies for planning and building civil infrastructures and urban systems, the

program can prepare them for success in this rewarding field. Students receive a balanced

education composed of the theoretical and practical knowledge they need to become a valued

professional. The program provides them with the basic knowledge and skills to enter the civil

engineering profession.

Program Outcomes

In possession of a BSc degree civil engineers will be one of the broader of the engineering

disciplines both in terms of the range of problems that fall within its purview and in the range of

knowledge required to solve those problems.

Civil Engineering BSC program provides students with the following upon graduation:

ability to apply knowledge of mathematics, science and engineering;

ability to design and conduct experiments, as well as to analyze and interpret data;

ability to design a system, component, or process to meet desired needs;

ability to function in multidisciplinary teams;

ability to identify, formulate and solve engineering problems;

understanding of professional and ethical responsibility;

ability to communicate effectively;

broad education necessary to understand the impact of engineering solutions in a global

and societal context;

recognition of the need for and an ability to engage in life-long learning;

knowledge of contemporary issues;

ability to use the techniques, skills and modern engineering tools necessary for

engineering practice;

ability to apply mathematics through differential equations; probability and statistics;

calculus-based physics; general chemistry; and geology

ability to apply knowledge in the following four recognized major civil engineering areas:

structural engineering, geotechnical engineering, transportation engineering, water

resources engineering with a depth of focus in one or more of the four areas;

ability to conduct laboratory experiments and to critically analyze and interpret data in the

following four (4) recognized major civil engineering areas: structural engineering,

geotechnical engineering, transportation engineering, water resources engineering

ability to perform civil engineering design by means of design experiences integrated

throughout the professional component of the curriculum culminating in a senior design

experience;

ability to explain basic concepts in management, business, public policy, and leadership;

and explain the importance of professional licensure;

ability to apply knowledge of sustainability to civil engineering practice.

Program Educational Objectives

The aim for the teaching is to train civil engineers who are capable and suitable for

demonstrating the ability to solve complex civil engineering planning, design,

management, operations;

solving construction problems in the public sector and in private industry;

demonstrating that they can function ethically in the workplace;

improving their professional standing through lifelong learning;

4

demonstrating their potential for leadership;

communicating effectively;

their capacity to work in teams.

Subject modules

The curriculum contains the following subject modules:

Basics of natural sciences : 47 credits

Basics of Natural Sciences, Mathematics, Mechanics, Descriptive Geometry, Technical Drawing,

Technical Chemistry, Engineering Phisics, Informatics for Engine

Economics and humanities subjects: 21 credits

State Administration &Low, Introduction to Economics, Microeconomics, Management for

Engineers, Quality Management, Introduction to Ethics, Europien Studies,

Professional subjects: 88 credits

Geoinformatics, Geographical Information System, Hydraulics, Hydrology & Hydrogeology,

Basics of Environmental Engineering, Public Works, Water Management & Hydraulic

Structures, Construction Materials, Geology, Geotechnics, Urban & Regional Development,

Transportation Engineering, Building Construction, CAD Modelling, Theory of Design, Steel

Structures, Reinforced Concrete Structures, Timber & Masonry Structures, Construction

Management, Bridges & Structures 38 credits

Geographical Information System, Transportation Engineering, Hydrobiology, Protection of the

Aquatic Environment, Hydraulics, Hydrology & Hydrogeology, Construction Management,

Public Works, Water Quality Control, Water Resources Management

Urban Engineering Specification

Transportation Engineering, Public Works, Water & Sewage Treatment, Urban Planning, Urban

Management 19 credits

Structural Engineering Stream

Theory of Girders, Building Construction, Design of Buildings, Steel Structures, Reinforced

concrete Structures, Geotechnics, Construction Management, FEM Modelling 39 credits

Structural Architect Specification

Steel Buildings, Reinforced Concrete Buildings, Composite Structures, Engineering Timber

Structures, Strengthening of Structures, Design of Building 18 credits

Optional subjects: 12 credits

Thesis: 15 credits

Duration of studies: 7 semesters, contact hours:

ECTS credits: 240, internship: 4 weeks

The state examination

Conditions for taking the state examination are:

Fulfilling the requirement of the CE Bachelor Program by minimum 240 credit points

Diploma Project accepted by the internal and external tutor

Parts of the state examination:

Introducing the results of the Diploma Project in the frame of a 15 minutes oral

presentation including pptx slide show and review of the plans or research study

Proper answer on the questions of the State Examination Committee, defending

the thesis grade

5

Result of the final examination is determined by the arithmetic mean of the marks given by the

Final Examination Committee:

Defending of the Diploma Project (result of the oral presentation and the discussion)

(20%)

Two marks based on the written comment of the tutors (10% + 10%)

Three marks of the Compulsory Exam of Mathematics (10%), Mechanics (10%) and

Infrastructural/Structural Engineering (40%)

The result of the state exam

The arithmetic mean of the mark given by the State Examination Committee for

the defending of the diploma project and

the two marks of the professional oral exams

The classification of the degree

The result of the final examination expressed by lettering

EXCELLENT

GOOD

SATISFACTORY

SUFFICIENT

The thesis

The thesis is a written task which the students should solve relying on previous studies and

specialized national and international literature under the guidance of a tutor in one semester. The

diploma work must prove that the author can apply the acquired theoretical knowledge. A student

at Engineering Management MSc can choose any topic for the diploma work suggested by the

faculty or in occasional cases individual topics acknowledged by the head of the department. The

topics of the diploma work should be given in completely uniform manner and based on the

system of requirements set up by the head of the institute and the head of the department

responsible for the training. The diploma works are written with the close collaboration of the

candidate and the tutor.

Making and justifying the thesis the students of Engineering Management MSc proves that they

are able to use the learnt knowledge in practice, to summarize the fulfilled task and its results, to

solve creatively the tasks in their topics and to do professional work.

The formal requirements of the diploma work are detailed in the “Thesis formal requirements”

which is handed out to every candidate when they decide upon their topic. The diploma works

must be handed in to the department responsible minimum ten days before the beginning of the

final exam period. The thesis paper is evaluated by an external graduate professional who gives a

grade as well as a short written comment on it. The head of the department makes a proposal for

the final evaluation of the diploma work based on the comments. The diploma work receives a

grade from the final exam committee.

Civil Engineering BSc University of Debrecen Faculty of Engineering Full-time

from 2016/2017 Fall semester

Structural Engineering SpecializationN

r. Name of the Subject Code Prerequisites

L P E C L P E C L P E C L P E C L P E C L P E C L P E C L P E C

1 Basics of Engineering Calculations FMAT32S05-EN 0 2 s 0

2 Mathematics I MFMAT31S05-EN 2 2 ESE 5

3 Mathematics II FMAT32S05-EN 2 2 ESE 5 Mathematics I

4 Mathematics III MFMAT32S03-EN 1 2 AW5 3 Mathematics II

5 Mathematics Compulsory Exam MFMAT30S00-EN 0 0 FE 0 Mathematics II

6 Mechanics I (Statics) MFMEC31S05-EN 2 2 ESE 5 Mathematics I, Engineering Physics

7 Mechanics II (Strength of Materials) MFMEC32S05-EN 2 3 ESE 5 Mechanics I

8 Mechanics III (Dynamics) MFMEC33S05-EN 2 2 ESE 5 Mechanics I

9 Mechanics Compulsory Exam MFMEC30S00-EN 0 0 FE 0 Mechanics III

10 Descriptive Geometry I MFABR31X04-EN 2 2 ESE 4

11 Technical Drawing MFMAB31S03-EN 1 2 AW5 3

12 Technical Chemistry MFKEM31S03-EN 2 1 ESE 3

13 Engineering Physics MFMFI31S03-EN 2 1 ESE 3

14 Informatics for Engineers I MFINF31X03-EN 0 2 AW5 3

15 Informatics for Engineers II MFINF32X03-EN 0 2 AW5 3 Informatics for Engineers I

16 State Administration and Law MFJOG31X02-EN 2 0 ESE 2

17 Introduction to Economics KTE10300K03-EN 2 0 ESE 4

18 Microeconomics KTE10310K03-EN 2 2 AW5 4 Introduction to Economics

19 Management for Engineers MFMFE31X03-EN 1 2 ESE 3

20 Quality Management MFQMA31X03-EN 2 0 ESE 3 Management for Engineers

21 Introduction to Ethics MFITE31X03-EN 2 0 AW5 3

22 European Studies MFEUI31X02-EN 2 0 AW5 2

23 Geoinformatics I MFGIN31S04-EN 2 2 AW5 4

24 Geoinformatics II MFGIN32S04-EN 2 2 ESE 4 Geoinformatics I

25 Geographical Information System (GIS) I MFTIN31S03-EN 1 2 AW5 3 Geoinformatics II

26 Hydraulics I MFHID31S04-EN 2 2 ESE 4 Engineering Physics

27 Hydrology & Hydrogeology I MFHIO31S04-EN 2 2 ESE 4 Hydraulics I

28 Basics of Environmental Engineering MFKOR31S03-EN 2 1 AW5 3 Technical Chemistry, Hydrology & Hydrogeology I

29 Public Works I (Water Public Works) MFKOZ31S04-EN 2 2 ESE 4 Hydraulics I

30 Water Management & Hydraulic Structures MFVIZ31S04-EN 2 2 AW5 4 Public Works I, Hydrology and Hydrogeology I

31 Construction Materials I MFEPA31S03-EN 2 1 AW5 3 Engineering Physics, Technical Chemistry

32 Construction Materials II MFEPA32S03-EN 2 1 ESE 3 Construction Materials I

33 Geology MFGEO31S03-EN 2 0 ESE 3

34 Geotechnics I (Soil Mechanics) MFGTH31S04-EN 2 2 ESE 4 Mechanics II, Geology

35 Geotechnics II (Earthworks) MFGTH32S04-EN 2 2 ESE 4 Geotechnics I

36 Geotechnics III (Foundation Engineering) MFGTH33S04-EN 2 2 ESE 4 Geotechnics I

37 Urban & Regional Development MFTEL31S03-EN 2 0 AW5 3

38 Transportation Engineering I (Roads) MFKLE31S03-EN 2 1 ESE 3 Geoinformatics I

39 Transportation Engineering II (Railways) MFKLE32S03-EN 2 1 ESE 3 Geoinformatics II

40 Building Construction I MFMAG31S04-EN 2 2 ESE 4 Technical Drawing

41 CAD Modelling I MFCAD31S04-EN 0 4 AW5 4 Descriptive Geometry I

42 Theory of Design MFMEL31S04-EN 2 2 ESE 4 Mechanics I

43 Steel Structures I MFACS31S03-EN 2 1 AW5 3 Construction Materials II, Theory of Design

44 Reinforced Concrete Structures I MFVBS31S03-EN 2 1 AW5 3 Construction Materials II, Theory of Design

45 Timber & Masonry Structures MFFFS31S03-EN 2 1 AW5 3 Theory of Design

46 Construction Management I MFKIV31S03-EN 1 2 AW5 3 Management for Engineers

47 Bridges & Structures MFMUT31S04-EN 2 2 ESE 4 Geotechnics III

48 Theory of Girders I MFTST31SS3-EN 1 2 ESE 3 Mechanics III

49 Theory of Girders II MFTST32SS3-EN 1 2 ESE 3 Theory of Girders I, Building Construction I

50 Building Construction II MFMAG32SS3-EN 2 2 ESE 4 Building Construction I, Building Construction II

51 Building Construction III MFMAG33SS4-EN 2 2 ESE 4 Building Construction II, Building Construction I

52 Design of Buildings I (Residental Buildings) MFETE31SS3-EN 1 2 ESE 3

53 Steel Structures II MFACS32S03-EN 2 1 ESE 3 Steel Structures I

54 Steel Structures III MFACS33SS3-EN 2 1 ESE 3 Steel Structures II

55 Reinforced Concrete Structures II MFVBS32S03-EN 2 1 ESE 3 Reinforced Concrete Structures I

56 Reinforced Concrete Structures III MFVBS33SS3-EN 2 1 ESE 3 Reinforced Concrete Structures II

57 Geotechnics IV MFGTH34SS3-EN 2 0 ESE 3 Geotechnics II, Geotechnics III

58 Construction Management II MFKIV32S03-EN 1 2 AW5 3 Construction Management I

59 FEM Modelling I MFVEM31SS3-EN 0 4 AW5 4 Steel Structures II, Reinforced Concrete Structures II, Theory of Girders I

60 Structural Engineering Compulsory Exam MFKSS31SS0-EN 0 0 FE 0 Steel Structures III, Reinforced Concrete Structures III, Construction Management II

61 Steel Buildings MFMAC31SM3-EN 2 1 AW5 3 Steel Structures III

62 Reinforced Concrete Buildings MFMVB31SM3-EN 2 1 AW5 3 Reinforced Concrete Structures III

63 Composite Structures MFMÖS31SM3-EN 2 0 AW5 3 Steel Structures II, Reinforced Concrete Structures II

64 Engineering Timber Structures MFMFS31SM3-EN 2 0 AW5 3 Timber & Masonry Structures

65 Strengthening of Structures MFSZM31SM3-EN 2 0 AW5 3 Steel Structures III, Reinforced Concrete Structures III

66 Design of Buildings II (Industrial & Agricultural Buildings) MFETE32SM3-EN 1 2 ESE 3 Design of Buildings I

67 Thesis MFSZA31SS15-EN 0 12 AW5 15 Steel Structures III, Reinforced Concrete Structures III

Optional Subject I 2 0 AW5 3

Optional Subject II 2 0 AW5 3

Optional Subject III 2 0 AW5 3

Optional Subject IV 2 0 AW5 3

68 Geoinformatics Laboratory MFGIG31S00-EN Geoinformatics I

69 Industrial Practice MFTELG3S00-EN

70 Structural Engineering Geoinformatics Laboratory MFSGG31SS0-EN Geoinformatics II, Geoinformatics Laboratory Practice

71 Material & Structural Engineering Laboratory MFFAM31SS0-EN Construction Materials II, Steel Structures II, Reinforced Concrete Structures II

Credits in the semester: 30 33 36 35 33 33 25 15Number of lectures/practical classes in the semester: 15 14 14 15 18 14 20 13 16 16 16 15 15 6 0 12

Number of ESE in the semester: 4 5 7 5 7 6 3 0

Number of AW5 in the semester: 5 4 3 4 2 3 5 1

Credits total: 240

Number of lectures/practical classes total: 219

Number of ESE total: 37

Number of AW5 total: 27

Abbreviations:

L= Lecture

P= Practice

E= Evaluation

C= Credits

ESE= exam

AW5= mid-semester grade

6th sem.

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FE= final exam

s= signature

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7

Basic Science Subjects

Basics of Engineering Calculations

Code: MFTTA31X00-EN

ECTS Credit Points: 0

Year, Semester: 1st year/1

st semester

Number of teaching hours/week:

Lecture: 0

Practice: 2

Prerequisites: -

Topics:

Numbers and Basic Operations: Fractions, decimals. A ratio, a proportion, a percentage.

Calculations with fractions. Handling exponents. Rounding and estimating. Normal forms of

numbers (scientific notation). Prime numbers, prime factorization.

Geometry: Points, lines, planes, segments, rays. Distance between points. Angles, types of

angles. Parallel lines and transversals. Vectors, vector operations. Types of triangles (scalene,

isosceles, equilateral, right). Congruent triangles. Centers of triangles. Polygons, interior and

exterior angles of a polygon. Quadrilaterals. Characteristics of parallelograms. Kites and

trapezoids. Transformations (reflection, rotation, translation). Similar polygons, a scale factor.

Similar triangles. Right triangles. Pythagorean theorem. Parts of a circle, angles. Perimeter and

area: triangle, quadrilaterals, general polygons, circles. Surface area and volume: polyhedral,

prisms, cylinders, pyramids, cones, spheres. Constructing lines, angles, polygons, circles and

arcs.

Functions, equations and inequalities: Basic functions (polynomial, power, exponential,

logarithmic, trigonometric), graphs and properties. Shifting and scaling. Linear functions

equations and inequalities. Graphical solution. Rates of change (examples in physics). Quadratic

polynomials equations and inequalities. Factoring. Exponential, logarithmic, trigonometric

equations and inequalities.

Statistics: Random events. Probability. Classical probability formulas. Conditional probability.

Empirical probabilities based on specific sample data. Percentile rank of an item in a data set,

first, second, and third quartiles. Histogram, cumulative frequency histogram, a box-plot diagram.

A scatter plot. Discrete and continuous random variables. Mean, median, mode, standard

deviation, variance. Linear regression models. Normal distribution.

Literature:

Mitas, P.J., Basic Math Quick Reference eBook, ISBN 978-0-615-27390-7

Zegarelli, M., Basic Math & Pre-Algebra for dummies, Wiley Publishing, Inc.

Freeman, C.M., Hand-On-Geometry, Prufrock Press Inc., ISBN-13: 978-1-59363-555-8

Alexander, D.C., Koeberlein, A., Elementary Geometry for College Students, BROOKS/COLE, 2011

Larson, R., Farber, B., Elementary Statistics - Picturing the World, Prentice Hall, 2012

Mathematics I

Code: MFMAT31S05-EN

ECTS Credit Points: 5 Year, Semester: 1

st year/1

st semester


Lecture: 2

Practice: 3

8

Prerequisites: -

Topics:

Arithmetic of real and complex numbers. Algebra of vectors in 2 and 3 dimensions. Coordinate

systems. Functions and their graphs. Composition of functions. Inverse functions. Sequences and

series of numbers, and convergence criteria. Sequences and series of functions, power series,

convergence criteria. Real functions. Polynomials. Limits, continuity. Interpolation. Arithmetic of

matrices. Determinants. Systems of linear equations. Cramer's rule. Linear space, subspace,

generating systems, bases, orthogonal and orthonormal bases. Linear transformations,

eigenvectors, eigen values.

Literature:

1. Thomas’ Calculus, Addison Wesley (11th edition, 2005), ISBN: 0-321-24335-8

2. S. Minton, Calculus Concept and Connections, McGraw Hill (2006), ISBN 0-07111200-6

Mathematics II

Code: MFMAT32S05-EN


st year/2

nd semester


Lecture: 2

Practice: 3

Prerequisites: Mathematics I.MFMAT31S05-EN

Topics:

Derivatives, linear approximation. Differentiation rules. Applications in physics. Taylor

polynomials. Extreme values. Monotony and convexity testing. Mean value theorems, l'Hospital's

rule, Taylor’s theorem. Curve sketching for a function, local and absolute extrema.

Antiderivatives. Integration by parts and by substitution. Integration in special classes of

functions. The Riemann integral. The Newton-Leibniz theorem. Improper integrals. Applications

of the integration in geometry and physics. Fourier series. Classification of differential equations.

Initial value problems, boundary value problems. First order differential equations. Slope fields.

Euler’s and Runge-Kutta methods. Problems leading to differential equations. Separable

differential equations. Second order differential equations. The theory of linear differential

equations, method of variation of parameters, method of undetermined coefficients, application of

the Laplace transform.

Literature:



3. M. D. Greenberg, Fundamentals of engineering analysis, Cambridge University Press,

ISBN 978-0-521-80526-1

Mathematics III

Code: MFMAT33S03-EN


nd year/1

st semester


Lecture: 2

Practice: 2

Prerequisites: Mathematics II.MFMAT32S05-EN

Topics:

9

Functions of several variables, and scalar fields. Continuity, differential and integral calculus,

partial derivatives, gradients, and Young's theorem. Local and global extrema. Double and triple

integrals. The Jacobian determinant. Vector-valued functions and curves. Derivatives. Linear

approximation. Curvature, torsion. Motion in space, velocity, acceleration. Vector fields.

Derivatives. Divergence and curl. Line and surface integrals. The theorems of Gauss and Stokes,

Green’s formulae. Conservative vector fields, potentials. Applications in physics.

Literature:



3. M. D. Greenberg, Fundamentals of engineering analysis, Cambridge University Press,

ISBN 978-0-521-80526-1

Mechanics I (Statics)

Code: MFMEC31S05-EN

Classes/week: 2+2 hours


Prerequisites: MFMAT31X05-EN, MFMFI31S03-EN

Topics:

Fundamentals of Mechanics and Statics. Force, moment, force-couple. Reduction of a force

system. Equilibrium equations Statics of material point. Statics of rigid body (moment, system of

planar forces). Static problems of planar systems. Internal force system of rigid body. Loadings

of beams (cantilevers, freely supported beams, fraction lined beams). Statically determined beam

structures (hinged-bar system, compound beams, trussed bars). Practical structures (friction).

Forces and rigid bodies in plane and in space. Simple structures. Compound structures. Trusses.

Internal forces. Force systems in three dimensional space. Structures in three dimensional space.

Literature:

1. Joseph F. Shelley: 800 solved problems in vector mechanics for engineers, Volume I:

Statics. (SCHAUM’S SOLVED PROBLEM SERIES)

2. Ferdinand P. Beer, E. Russell Johnston, Jr., (1987): University of Connecticut, Mechanics

for Engineers: Statics and Dynamics (Package), 4th Edition, ©1987, ISBN-13

9780070045842

3. Russel C. Hibbeler (2006): Engineering Mechanics – Statics and Dynamics, Prentice Hall,

2006. ISBN-13 9780132215091

4. Lakshmana C. Rao, J. Lakshminarasimhan, Raju Sethuraman, Srinivasan M. Sivakumar

(2004): Engineering Mechanics: Statics and Dynamics, PHI Learning Pvt. Ltd., ISBN

8120321898, 9788120321892

5. Lawrence E. Goodman, Susan Goodman, William H. Warner (2001): Statics

Courier Dover Publications, ISBN 0486420051, 9780486420059

6. Ferdinand Beer, E. Russell Johnston: Vector Mechanics for Engineers ISBN

10: 0070042780 / 0-07-004278-0

ISBN 13: 9780070042780, Publisher: McGraw-Hill Publication Date: 1977

7. Vector Mechanics for Engineers by Ferdinand P. Beer, E. Russell Johnston and Phillip J.

Cornwell (2012, Hardcover) ISBN-10: 0077402324 | ISBN-13:9780077402327

Mechanics II

Code: MFMEC32S05-EN



https://www.me.bme.hu/sites/default/files/courses/statics_week08draft.pdf

10

Prerequisites: MFMEC31S05-EN

Topics:

Statics review. Mathematical preliminaries (vector, matrix and tensor algebra). Fundamentals of

strength of materials. Polar moment of inertia. State of stresses. Principal values of normal

stresses, principal axes. Strain energy. Constitutive equations (Hooke’s law). Simple loadings

(tension, compression, bending, torsion, shear). Axial Loading: normal stress. Hooke’s Law,

modulus of elasticity. Design methods. Moment of inertia and product of inertia. Elastic and

plastic deformations. Physical interpretation of strain terms. State of deformation. Determination

of principal axes. Mohr’s circle. Combined loadings (tension and bending, inclined bending,

eccentric tension, tension and torsion, bending and torsion). Buckling of columns. Energy

methods (Betti’s theorem). Stress Transformations.

Literature:

1. Stephen Timoshenko (1955): Strength of Materials: Elementary Theory and Problems,

Van Nostrand

2. Jacob Pieter Den Hartog (1961): Strength of Materials, Courier Dover Publications,

3. ISBN 0486607550, 9780486607559

4. Ladislav Cerny (1981): Elementary Statics and Strength of Materials, McGraw-Hill,

ISBN 0070103399, 9780070103399

5. Ferdinand P. Beer, E. Russel Johnston, Jr., John T. DeWolf (2006): University of

Connecticut Mechanics of Materials, 4th Edition, © 2006, ISBN-13 9780073107950

6. Beer, Johnston: Mechanics of materials (3rd

edition, 2004), ISBN: 13-978-0-07-053510-7

7. Budynas: Advanced Strength and Applied Stress Analysis (2nd

edition, 1998), ISBN-

13978-0070089853

8. Popov: Mechanics of materials (2nd

edition 1976) ISBN-13: 978-0135713563

Mechanics III (Dynamics)

Code: MFMEC33S05-EN




Topics:

Kinematics of material point. Kinetics of material point. Kinematics of rigid bodies. Kinetics of

rigid bodies. Impact problems. Free, and forced vibration problems with one degree of freedom.

Free and forced vibration problems with more degrees of freedom. Vibration forced by support

motion.

Literature:

1. F.P. Beer, E.R. Johnston: Dynamics

2. S. Timoshenko: Vibration problems in engineering.

3. E. C. Pestel, W. T. Thomson: Dynamics

4. C. M. Harris, C. E. Crede: Shock and vibration handbook

Descriptive Geometry

Code: MFABR31X04-EN



Prerequisites: None

11

Topics:

Monge-representation: Making images, methods of projection, the Monge image-plane system,

representation of space elements, space elements of special place, reconstruction, integration.

Fundamentals of intersection: Designing a stabbing point under normal and special cases, planes

and plane-plates intersection. Fundamental tasks of metricity: Perpendicularity, distance and

angle tasks, rotation of a plane into an image-plane, image-plane transformations, designing

graphical picture by image-plane transformation, visibility. Plane bodies: Representation of them,

their plane intersection, their interpenetration. Surfaces: Construction of surfaces, representation

of surfaces, their plane intersection, interpenetration of surfaces.

Literature:

1. Paré, E. G.: Descriptive geometry, Prentice Hall, 1997

2. Gordon, V. O.: A course in descriptive geometry, Mir, 1980

3. Hood, G. J. and Palmerlee, A. S.: Geometry of Engineering Drawing, 4th ed., McGraw-

Hill, 1958

Technical Drawing

Code: MFMAB31S03-EN



Prerequisites: None

Topics: Classification of projection methods. Multi-view orthogonal projection, use of picture planes.

Fitting, joining and intersecting problems. Successive auxiliary views. Defining true shape of

objects. Defining and projecting of polyhedrons. Affinity and collineation. Section of

polyhedrons, operations in solid geometry. Axonometrical systems, orthogonal and oblique

projection. Topographic map. Generating and descripting curved surfaces. Generating and

descripting warped surfaces. Basics of technical drawings, common system of notations, symbol

of materials. Role of the human body in determining dimensions. Concept and technical content

of groundplan and section. Elevation. Free-hand sketches of constructions, renders.

Literature:

1. J. Böhönyey (1986) Building construction encyclopedia. Iparterv, Budapest ISBN : -

2. Madan Mehta (1997) The principles of building construction. Prentice Hall ISBN :

0132058812

3. Ralph W. Liebing (1999) Architectural Working Drawings. Wiley ISBN-10: 0471348767

Technical Chemistry

Code: MFKEM31X03-EN



Prerequisites: None

Topics:

The series of lectures are based on the topics of general chemistry. Atomic theory, chemical

bonding, structure. Definitions, elements, chemical equations. Gases, liquids and solutions.

Concentration, chemical reactions. Chemical technologies, modeling. Chemical basis of

engineering materials such as cement, adhesives, polymers, fuels, metals and semiconductors.

http://www.google.hu/search?hl=hu&tbo=p&tbm=bks&q=inauthor:%22Madan+Mehta%22

12

Literature:

1. Tom Holme, Larry Brown: Chemistry for Engineering Student, Publisher: Brooks Cole,

Hardcover: 653 pages, 2006, Paperback ISBN-10: 0534389740,

2. James O. Glanville: General Chemistry for Engineers, Preliminary Edition (Paperback)

Paperback: 663 pages, Publisher: Prentice Hall; Prl edition, 2000, ISBN-13: 978-

0130325143

3. Darrell Ebbing, Steven D. Gammon: General Chemistry (Hardcover) Publisher: Brooks

Cole; 9 edition, 2007, 1030 pages ISBN-13: 978-06188574871. Joseph

Engineering Physics

Code: MFMFI31G02-EN


st year/1

st semester


Lecture: 2

Practice: 0

Prerequisites: -

Topics:

The basics of kinematics and dynamics of particles. Giving the position of a particle. Position-

time function, velocity and acceleration. Newton’s laws. Types of forces. The concept of

mechanical work, potential and kinetic energy. Work-energy theorem.

The basics of electricity and magnetism. Transport processes. Electrostatics, electrical potential,

electric fields around conductors, capacity and capacitors. Transport processes. Electric current,

AD circuits. A heat transfer: thermal conduction, convection and radiation. The fields of moving

charges, magnetic fields, electromagnetic induction and Maxwell’s equations, AC circuits,

electric and magnetic fields in matter.

Literature:

1. Alvin Halpern (1988): 3,000 Solved Problems in Physics (SCHAUM’S SOLVED

PROBLEM SERIES), McGraw-Hill, 1988, ISBN 0-07-025734-5

2. Michael Browne (1999): Physics for Engineering and Science, McGraw-Hill, 1999, ISBN

0-07-161399-6

3. Robert Balmer (2006) Thermo-dynamics, Jaico Publishing House, ISBN: 817224262X, 868

pages

Economics and Humanities Subjects

Economics for Engineers

Code: MFKGZ31X04-EN


nd year/1

st semester


Lecture: 3

Practice: 0

Prerequisites: -

Topics:

This course focuses on the theory and application of the following:

Measuring national income and output (real vs. nominal GNP, GDP, NNP, NDP, the problem of

double counting). Consumption and Investment. IS model. Economic role of government

(externalities). Fiscal policy and output determination. The role of money in the economy, the

http://www.amazon.com/exec/obidos/search-handle-url/ref=ntt_athr_dp_sr_1?%5Fencoding=UTF8&search-type=ss&index=books&field-author=James%20O.%20Glanville

http://www.amazon.com/exec/obidos/search-handle-url/ref=ntt_athr_dp_sr_1?%5Fencoding=UTF8&search-type=ss&index=books&field-author=Darrell%20Ebbing

http://www.amazon.com/exec/obidos/search-handle-url/ref=ntt_athr_dp_sr_2?%5Fencoding=UTF8&search-type=ss&index=books&field-author=Steven%20D.%20Gammon

13

evolution of money, central bank, commercial banking, supply and demand for money. Monetary

policy (varieties and problems of monetary policy). IS-LM analysis: the integration of the goods

and money market models. Aggregate demand and supply. Labour market. Unemployment and

inflation.

Literature:

1. T. KISS, J., Introduction to Macroeconomics for Engineers and technical Managers.

University of Debrecen Faculty of Engineering. Debrecen University Press, 2014. ISBN:

978 963 318 416 5.

2. SAMUELSON P.A., NORDHAUS W.D.: Economics, 18th edition, Academic Internet

Publishers Inc., 2006. ISBN: 0072872055

3. PARKIN, M., POWELL, M. & MATTHEWS, K. (2008) Economics. 7th ed. Harlow:

Addison

Wesley. ISBN-13: 9780132041225

Microeconomics

Code: MFVGF31X04-EN


nd year/2

nd semester


Lecture: 1

Practice: 2

Prerequisites: Economics for Engineers MFKGZ31X04-EN

Topics:

This course aims to make students familiar with the basic concepts of microeconomic analysis. In

particular, the course will be focused on the analysis of how economic actors, consumers and

firms choose between different alternatives. By the end of the course, the student should be able

to use the basic tools and models of microeconomics, and apply them in solving problems. The

course focuses on the theory and application of the following: The basics of supply and demand.

Market equilibrium. Elasticity of demand (supply). Consumer behavior - Households’ choices

(Marginal utility theory, indifference (curve) analysis. Firm’s production (factors), costs of

production, profit-maximizing behavior. Market structures (perfect competition, imperfect

competition: monopoly, oligopoly, monopolistic competition). Profit maximizing under perfect

competition, and monopoly. Investment, interest, profits and capital.

Literature:

1. BESANKO, DAVID – BREAUTIGAM, RONALD R.: Microeconomics. Third Edition

(International Student version). John Wiley and Sons, Inc., New York, 2008.

2. BESANKO, DAVID – BREAUTIGAM, RONALD R.: Microeconomics. Study Guide.

Third Edition. John Wiley and Sons, Inc., New York, 2008.

3. GREGORY MANKIW: Principles of Microeconomics, 4th edition. South-Western College

Pub, 2006

4. GREGORY MANKIW: Principles of Microeconomics - Study Guide. South-Western

College Pub, 2006

Basics of Quality Management

Code: MFMIN31X04-EN

ECTS Credit Points: 4 Year, Semester:3

rdyear/1

stsemester


http://www.amazon.com/exec/obidos/search-handle-url/index=books&field-author-exact=N.%20Gregory%20Mankiw&rank=-relevance%2C%2Bavailability%2C-daterank/102-3419914-6414520

http://www.amazon.com/exec/obidos/search-handle-url/index=books&field-author-exact=N.%20Gregory%20Mankiw&rank=-relevance%2C%2Bavailability%2C-daterank/102-3419914-6414520

http://www.textbooks.com/BooksDescription.php?BKN=702901&TYP=SBJ&TXT=microeconomics%20mankiw&CSID=MCK0COO0DO0MQDUMKQCQC

14

Lecture: 1

Practice: 1

Prerequisites: -

Topics:

This course focuses on making the theories and principles of total quality both practical and

useful ways. Practitioners in a corporate setting will find it a valuable guide in helping them to

learn how to be effective agents of the total quality approach, to understand and implement total

quality.

Literature:

1. Goetsch D. L. – Davis, S. (2006): Quality management: introduction to total quality

management for production, Pearson Prentice Hall, ISBN 0131189298, 9780131189294

2. Dale, B. G. (2003): Managing Quality, Wiley-Blackwell, ISBN 0631236147,

9780631236146

Management for Engineers

Code: MFMAM31X04-EN


Year, Semester: 3rd

year/2nd

semester


Lecture: 1

Practice: 3

Prerequisites: -

Topics:

In the Management for Engineers course students gain in sight into the key areas of leadership.

During the course students become familiar with the new management trends, such as coaching

authoritarian leadership, time- and energy management and with the importance of emotional

intelligence in effective leadership. In the framework of practical classes the students’ leadership

skills, emotional intelligence and their soft skills are measured and analyzed.

Literature:

1. McKeown, A. – Wright, R. (2011): Professional English in Use, Cambridge University

Press, Cambridge

2. Gordon, T. (2001): Leader Effectiveness Training, New York, Widden Books

3. Schwart, T – Loehr, J. (2005): The Power of Full Engagement: Managing Energy, Not

Time, Is the Key to High Performance and Personal Renewal, New York, Free Press

4. Mancini, M. (2003): Time management, New York, McGraw-Hill Companies

5. Taylor, J. (2012): Decision Management System, IBM Press, USA

State administration and Law

Code: MFJOG31X02-EN

ECTS Credit Points:2 Year, Semester: 3

rdyear/1

st semester


Lecture: 2

Practice: 0

Prerequisites: -

Topics:

15

Legal systems of the world, civil and human rights, the main characteristics and structure of the

Hungarian Law System, major rules of commercial law and proprietary rights, evolution, history

and development of the European integration.

Literature:

1. Zoltán Horváth: Handbook on the European Union, HVG-ORAC, Budapest, 2011.

2. Péter Smuk: The transformation of the Hungarian Legal System 2010-2013. Complex,

2013.

Engineering Ethics

Code:MFTAI31X02-EN


st year/2

nd semester


Lecture: 2

Practice: 0

Prerequisites: -

Topics:

This course is intended to introduce students to the study of ethics, the branch of philosophy that

aims to understand what actions are right and wrong, what states of affairs are good and bad, and

what traits of personality are desirable and undesirable. Our central question will be “What

should I (morally) do?” Similarly, although it is impossible to separate the discussion of ethical

theories from their application to particular moral problems, this course will emphasize the

former. The most well-developed and carefully formulated ethical theory that addresses our

central question is utilitarianism: what I should do to make the world a better place. In the second

half of we review of the growth and development of professions, engineering ethics, obligations

to employers and their peers, limits of professional responsibility, codes of ethics and

enforcement. Traditional function of engineering societies. Ethical engineers and the lows, the

public interest analyzing some case studies.

Literature:

1. Charles E. Harris, Michael S. Pritchard, Michael J. Rabins: Engineering Ethics: Concepts

and Cases, 2008 - 313 pages

Europien Studies

Code: MFEUI31X02-EN



Prerequisites: None

Topics:

History of the European Union. Community law. Economics and industry. Agriculture of the EU.

Social and political questions. The process of enlargement. EU and the rest of the world.

Operation of the EU: presidency, committees, parliament. Regional and cohesional policy. Focus

areas.

Literature:

1. R. Thomson, F.N. Stokman, C.H. Achen, T. König (eds.) (2006) The European Union

Decides. Cambridge University Press, Cambridge. ISBN 978-052-186-1-892

2. R. Dannreuther (2012) European Union Foreign and Security Policy: Towards a

Neighbourhood Strategy. Routledge, London. ISBN 0-415-32297-9

16

3. H. Lelieveldt, S. Princen (2011) The Politics of the European Union. Cambridge

University Press, Cambridge. ISBN 978-052-151-8-628

4. D. Watts (2008) The European Union. Edinburgh University Press, Edinburgh. ISBN

978-0-7486-3297-8

Specific compulsory subjects

Informatics for Engineers I

Code: MFINF31X03-EN


st year/1

st semester


Lecture: 0

Practice: 2

Prerequisites: -

Topics:

Introduction to informatics. Computer structures. Operating systems. Computer networks, the

Internet. Theoretical and practical data structures. Algorithms. Spreadsheets: entering data,

records, fields, creating a table, sorting and filtering data, expanding databases, formatting

databases. Relational databases, SQL language, normalizing databases, securing databases

(confidentiality, integrity and availability), keys, transactions.

Literature:

1. J. Walkenbach, Excel 2007, Wiley Publishing Inc.

2. C. N. Prague, M. R. Irwin, J. Reardon, Access 2003 Bible, Wiley Publishing Inc.

Informatics for Engineers II

Code: MFINF32X03-EN


st year/2

nd semester


Lecture: 0

Practice: 2

Prerequisites: Informatics for Engineers I. MFINF31X03-EN

Topics:

Definitions and basics of CAD, geometric modeling, computer graphics. Blocks, customizing,

dimensioning, drawing commands, drawing Aids, file formats, images paper space and model

space, plotting, programming, rendering, sheet sets, tables, text. Computer programs, program

design, programming methods, program structures. Programming languages: basics, data types,

variables, programming structures, subroutines, modules. Programming with LabVIEW,

applications in engineering. Creating subVI, loops, charts, arrays, clusters, graphs, case and

sequence structures, data acquisition, instrument control.

Geoinformatics I

Code: MFGIN31S04-EN



Prerequisites: None

17

Topics:

The principle of place definition. Reference systems (horizontal, vertical). Projection systems.

Important domestic projections (geodesic, geographic). International and domestic basic point

networks (horizontal, vertical, 3D). Methods of defining basic points and connecting points.

Creating polilines, assessing equipment. Analogous, analytical and numeric assessing

procedures. Otrophoto. Inner, relative and absolute transformations. Applying photogrammetry.

Basic geodesic instruments and measuring methods. Getting acquainted with and practicing with

the tools. Location definition with satelites. Using manual navigation GPS equipment. Basic

concepts of space information technology. Space information systems (construction,

characterization, models, applications).

Literature:

1. Wolfgang Torge, Jürgen Müller (2012): Geodesy ISBN: 978-3-11-025000-8

2. Wolfgang Torge (2001): Geodesy ISBN: 3-11-017072-08

3. James A. Elithorp, Jr. and Dennis D. Findorff: GeodesyforGeomatcs and GIS

Professionals, 2nd editionedition)

Geoinformatics II

Code: MFGIN32S04-EN



Prerequisites: MFGIN31S04-EN

Topics:

By using an interactive map constructing programme we present the means of map construction

as well as the basic rules of map making and their graphic presentation. Making different types of

files and theoptions of their application. Presenting, interpreting and using the menu and the

tools. The basic condtions of construction. The methods of picture design. Creating layers and

their significance. Applying filters in the course of picture design.Types of views and their

significance. Validating map making principles in the course of construction. The insertion of

graphs into context and the design of pictures. Opportunities of map making. The methods of

graphic presentation. Options of printing and application.

Literature:

1. Wolfgang Torge, Jürgen Müller (2012): Geodesy ISBN: 978-3-11-025000-8

2. Wolfgang Torge (2001): Geodesy ISBN: 3-11-017072-08

3. James A. Elithorp, Jr. and Dennis D. Findorff: GeodesyforGeomatcs and GIS

Professionals, 2nd editionedition)

Geographical Information System I (GIS)

Code: MFTIN31S03-EN




Topics:

Basics of geographic information systems. Application of GIS in technical and civil engineering

practice. The concept of information systems. The role of location-based information.

Information systems components and application. Process of data modelling. Geometric data

reference systems. Data sources and data collection methods. Technical background of GIS

systems, their operational development perspectives, and their realization problems. The goal of

18

the practice is to train topographic and remote sensing based data capture, the collection of

geometric information. They execute a map update task by aerial images.

Literature:

1. Christopher B. Jones (1997): Geographical information systems and computer

cartography, ISBN: 0582044391

2. Paul A. Longley (2005): Geographical information systems and science, ISBN:

047087001X (pbk)

Hydraulics I

Code: MFHID31S04 EN



Prerequisites: MFMFI31S03-EN

Topics:

Elementary fluid mechanics. Understanding of the fundamental principles of hydrostatics and

hydrodynamics; the basic ideas of dimensioning of hydraulic structures and hydraulic machinery.

Hydrostatics (absolute and relative equilibrium, pressure head diagrams and buoyancy).

Application of the Bernoulli equation (laminar and turbulent flow in pipes, losses and pipe

systems). The impulse momentum equation, open channel flow (Chezy). Specific energy,

supercritical and subcritical flow, hydraulic jump, stilling basins. Hydraulic machinery.

Literature:

1. Solomon Alemu (1992) Essentials of Hydraulics / AAU Printing Press

2. Bruce R. Munson, Donald F. Young, Theodore H. Okiishi, (2009) Fundamentals of Fluid

Mechanics, John Wiley and Sons, ISBN 978-0470262849, 776 pages

3. R. E. Featherstone (1995), Civil Engineering Hydraulics, Blackwell Ltd.

4. Y. Nakayama (1999), Introduction to fluid mechanics, Butterworth Heinemann

5. Streeter, V.a. (1997) Fluid Mechanics . McGraw – Hill

6. Marriott, M 2009, Nalluri & Featherstone's civil engineering hydraulics: essential theory

with worked examples, 5th ed., Wiley Blackwell, Oxford.

Hydrology and Hydrogeology I

Code: MFHIO31S04-EN



Prerequisites: MFHID31S04-EN

Topics:

Component of the water cycle, such as precipitation, evaporation and transpiration, runoff,

infiltration, and surface and ground water flow. Understanding of physical hydrologic principals,

processes and related observation/measurement techniques, calculation methods: including the

ability to critically analyze and apply that understanding to new problems.

Literature:

1. Martin R. Hendriks (2010):Introduction to Physical Hydrology, Oxford Press, 978-0-19-

929684-2

2. Roy Ward and Mark Robinson (2000): Principles of Hydrology (Fourth Edition),

McGraw-Hill International (UK), ISBN 0 07 709502 2

3. Philip B. Bedient, Wayne C. Huber and Baxter E. Vieux (2012): Hydrology and

19

Floodplain Analysis (5th Edition), ISBN-13: 978-0132567961

4. Lecture notes of the International Post-Graduate Course on Hydrology (UNESCO-

VITUKI) – one copy available at Beáta Pataki

5. Related – available recent – research project results and scientific articles about issues,

methods, results

Basics of Envorinmental Engineering

Code: MFKOR31S03-EN



Prerequisites: MFKEM31X03-EN, MFHIO31S04-EN

Topics: The most important current environmental issues, such us: sustainability, ecological footprint,

deforestation, climate change, wetlands, water and air pollution. Basic engineering principles and

the ecological approach. Most important ecological terms. Important mass cycles (H2O, C, O, N,

P). Adverse effects of pollution on the environment, pollution control strategies, environment

protection). Sustainable development, sustainable building, settlement and region. Management

approaches/tools (DPSIR chain, Environmental Impact Assessment, Ecosystem Services

approach). The main goals of the course are: to help understanding the complexity of

environmental problems, shaping attitude andbroadening knowledge of the new generation of

civil engineers to be able to use the system approach in technical planning and for solving

comprehensive environmental management, regulation and planning tasks. The course helps to

understand the effects of the engineering activities on the environment.

Literature:

As interdisciplinary and transdisciplinary approach prevails during the course, the

presentations (and partly the university notes – HEFOP/2004/3.3.1/0001.01 in Hungarian

languages) prepared for the Hungarian BSc are going to be translated and recent results of

research projects and scientific publications are also going to provided for the students.

Further readings:

1. D. Heinrich and H. Manfred (1994): Atlas of Ecology, Springer Verlag, pp. 296

2. M.E. Jensen and P.S. Bourgeron (2001): A Guidebook for Integrated Ecological

Assessments, Springer Verlag, ISBN 9780387985831

3. Guy R. McPherson, Stephen DeStefano (ed.) (2002): Applied Ecology and Natural

Resource Management, Cambridge University Press

4. W.Barthlott and M. Winiger (ed.) (2001): Biodiversity - A Challenge for Development

Research and Policy, Springer, ISBN 9783540639497

5. W. Steffen, J. Jäger, D.J. Carson, C. Bradshaw (ed.) (2003): Challenges of a Changing

Earth, Springer, ISBN 9783540433088

6. G. Bruce Wiersma (ed.) (2004): Environmental monitoring CRC Press, ISBN

9781566706414

ElectrotecPublic Works I

Code: MFKOZ31S04-EN



Prerequisites: MFHID31S04-EN

Topics: Basic technical parameters of water public work, water consumption and its features.

Water resources in Hungary ( in Europe). Water quality and water classification. Physical,

20

chemical and biological parameters. Water supply system. Water distribution system, network.

Types of sewers. Estimating wastewater flow. Sewer design. Storm water inlets. Manholes. The

basic designing instructions are presented for public utilities.

Literature:

1. Jonathan T. Ricketts, M. Kent Loftin, Frederick S. Merritt, Standard Handbook for Civil

Engineers, McGraw-Hill Publishing Company, 2003; ISBN 0-07-136473-0

Water management and hydraulic structures

Code: MFVIZ31S04-EN



Prerequisites: MFKOZ31S04-EN, MFHIO31S04-EN

Topics: Hydraulic structures are engineering structures constructed for the purposes of harnessing and

using water resources (groundwater, surface water, lakes, sea, etc) or for the prevention of the

negative and destructive actions (floods, shore erosion, etc) of water on the surrounding

environment. There are a large variety of hydraulic structures to serve the many purposes

for which water resources are put to use. Also case studies from Hungary’s complex water

management issues - water resources management, excess water problems, flood management,

settlement-scale water management issues, thermal water management, water quality control

management, etc. - are discussed. However, several issues like water utilities, water treatment and

water resources management are discussed in the frame of other courses, these get less emphasis

during this course. Main topics are Classification of hydraulic structures by purpose and types;

Site selection factors; wave pressure, wind load in the stability analysis; load conditions; sliding

stability; design of gravity dams; classification of reservoirs; Keywords: storage structures, flow

control structures, flow measurement structures, division structures , conveyance structures,

collection structures, collection structures, energy dissipation structures, shore protection

structures, river training and waterway stabilization structures, sediment and quality control

structures, hydraulic machines, dams, tanks, spillways, outlets, valves, gates, weirs, orifaces,

flumes, coffer dams, canal headworks, intake works, open channel, pressure conduit, drain

inlets, infiltration galleries, stilling basins, surge tanks, check dams, dikes, groins, revetments,

levees, cutoffs, locks, piers, culverts, sluiceways, racks, sedimentation tanks, storage dams,

diversion dams, detention dams, overflow dams , siphon spillway, crest, earthfill dam, zoned

earth dams, seepage flow, hydraulic failure, stability of earthfill dams

Literature:

1. WFD (Directive 2000/60/EC of the European Parliament and of the Council of 23

October 2000 establishing a framework for Community action in the field of water policy)

2. A practical guide to integrated land management methods intended to improve land use

and water management efficiency in the Tisza river basin; ICPDR 2010.

3. Download course material

4. Hydraulic Structures, Fourth Edition by P. Novak, A.I.B. Moffat, C. Nalluri, R.

Narayanan ISBN-10: 0415386268 ISBN-13: 978-0415386265 Published 21st December

2006 by CRC Press – 736 pages

Construction materials I

Code: MFEPA31S03-EN



http://www.taylorandfrancis.com/books/search/author/p_novak/

http://www.taylorandfrancis.com/books/search/author/aib_moffat/

http://www.taylorandfrancis.com/books/search/author/c_nalluri/

http://www.taylorandfrancis.com/books/search/author/r_narayanan/

http://www.taylorandfrancis.com/books/search/author/r_narayanan/

21

Prerequisites: MFKEM31X03, MFMFI31S03-EN

Topics: Introduction: Basic definitions. History of construction materials. Development of construction

materials. Grouping of construction materials. Rheology of materials. Idealisation diagrams.

Weight, density of solid and liquid type materials (with laboratory measurements). Aggregates.

Sieve curve (with laboratory measurements). Inorganic binder materials. Curing of binder

materials (with laboratory measurements). Modifiers. Concrete mix-design. Properties of fresh

concrete. Consistency of fresh concrete (with laboratory measurements). Concrete classes.

Exposition conditions of concrete. Hardened concrete properties (strength). Determination of

compressive strength of concrete with laboratory measurements with classification. Durability of

concrete. Special concrete types (FRC, SCC, HSC etc.)

Literature:

1. Hegger M., Auch-Schwelk V., Fuchs M., Rosenkranz T. (2006): Construction Materials

Manual, Birkhäuser Edition Detail, ISBN 3-7643-7570-1

2. Kind-Barkauskas, Kauhsen, Polonyi, Brandt. (2002): Concrete Construction Materials


Construction materials II

Code: MFEPA32S03-EN



Prerequisites: MFEPA31S03-EN

Topics: Glass as building material (types of glasses and properties of different glass types, mechanical

and physical properties of glass, introduction in possibilities of creating load bearing glasses.).

Wooden materials in building industry, mechanical and hidrotechnical properties (laboratory

testing of wood, effect of fiber direction on properties of wood, force-deflection diagrams,

determination of Young’s modulus etc.). Steel in engineering applications. Mechanical properties

of hot and cold formed steels. Stress-strain diagrams. Effect of carbon content on forming and

welding of steel. Laboratory tensile testing of steel (reinforcement). Hardness of steel. Effect of

temperature on the external work of steel (Charpy-hammer tests). Alloys. Plastics in engineering

applications. Organic binder materials (bituminous materials). Ceramic. History of ceramics.

Strength and durability of ceramic materials. Laboratory compression tests of bricks.

Literature:

1. Hegger M., Auch-Schwelk V., Fuchs M., Rosenkranz T. (2006): Construction Materials


2. Schultz H. C., Sobek, W., Haberman K.J. (2000): Steel Construction Manual, Birkhäuser

Publishers, ISBN 3-7643-6181-5

3. Herzog T., Natterer J., Schweizer R., Volz M. , Winter W. (2004): Timber Construction


4. Schittich, C., Staib, G., Balkow, D., Schuler, M., Sobek, W. (1999): Glass Construction

Manual, Birkhäuser Publishers, Basel, ISBN 3-7643-6077-1

5. Pankhardt, K. (2012): Load bearing glasses, LAP Lambert Academic Publishing, ISBN

978-3-8473-2191-0

6. Pfeifer G., Ramcke R., Achtziger J. et. al. (2001): Masonry Construction Manual,

Birkhäuser Basel, ISBN: 978-3-7643-6543-1

22

7. Knippers J., Cremers J., Gabler M., Lienhard J., (2012): Plastic and Membranes

Construction Manual, Birkhäuser Architecture, ISBN: 978-3-0346-0726-1

Geology

Code: MFGEO31S03-EN



Prerequisites: None

Topics: The geology provides the characterisaton of geological formations and materials from a civil

engineering point of view. It describes the processes and the interactions between the engineering

works and the geological environment. The dynamics of the Earth, the description of raw

materials and geo – materials used in engineering practice (minerals and rocks), the geological

risks such as earthquakes, volcanism, landslides and their effect, characterisation of surface and

subsurface waters and related geological problems.

Literature:

1. Bell, F. G.: Fundamentals of engineering geology. Butterwords, London, 1983.

2. Bell, F. G.: Engineering geology. 2nd edition, Elsevier, 2007.

3. Dr. Lajos Endrédi (2000): Geographisch cognition, National Coursebook Publishing

House, Budapest

4. Zoltán Borsy (1998): General Naturalgeography, National Coursebook Publishing House,

Budapest

5. József Juhász: Hydrogeology, Academy Publishing House

Geotechnics I

Code: MFGTH31S04-EN



Prerequisites: MFMEC32S05-EN, MFGEO31S03-EN

Topics: Origin of soils, soil exploration, soil samples. Components of soils (phase relationships, grain

size distribution, consistency limits), soil classification, compaction. Stresses in the soil (under

static conditions, conditions of steady vertical flow). Flow of water through soil due gravity

(Darcy’s law, coefficient of permeability, flow nets). Compressibility of soil (reasons and types

of compression). Shear strength of soil (Mohr-Coulomb failure criterion, determination of

shearing strength).

Literature:

1. Atkinson, J.: The Mechanics of Soils and Foundations. Taylor and Francis, London, 2007.

2. Craig, R. F.: Craig’s Soil Mechanics. Spon Press, Taylor and Francis Group, London,

2004.

3. Kempfert, H. G., Gebreselassie, B.: Excavations and Foundations in Soft Soils.

Springer,2006

4. Lambe, J., Whitman, G.: Soil mechanics, SI-Version. John Wiley and Sohn, New

York,1979.

5. Lancelotta, R.: Geotechnical Egineering. Balkema. Rotterdam, Brookfield, 1995.

6. Look, B.: Handbook of geotechnical investigation and design tables. Taylor and

Francis,London, 2007.

23

7. Lunne, T., Robertson, P. K., Powell, J. J. M.: Conee penetration testing in geotechnivcal

practice. Spon / Routledge, London, New York, 2002.

8. Terzaghi, K.: Theoretical soil mechanics. John Wiley and Sons, New York, 1943.

9. Terzaghi, K., Peck, R.: Soil mechanics in engineering practice. John Wiley and Sons,

10. New York, 1943.

11. Whitlow, R.: Basic soil mechanics. Longman Scientific and Technical, 1990.

Geotechnics II

Code: MFGTH32S04-EN



Prerequisites: MFGTH31S04-EN

Topics: Scope of earth works. Plastic limit states, Rankine earth pressures. Earth pressure and passive

resistance of real” walls. Soilstatical design of retaining structures. Stability of earth works.

Construction of earth works. The designal, executional and monitoring questions of construction.

Dewatering of earth works. Geosynthetics.

Literature:

1. Bell, F. G.: Engineering Geology and Construction. Taylor and Francis, London, 2004.

2. Hausmann, M.: Engineering principles of ground modification. Mc Graw – Hill

Publishing Company, New York, 1986.

3. Kempfert, H. G., Gebreselassie, B.: Excavations and Foundations in Soft Soils.

Springer,2006

4. Koerner, R. M.: Designing with Geosynthetics. Prentice Hall, Eaglewood Cliffs, 2005.

Geotechnics III

Code: MFGTH33S04 EN



Prerequisites: MFGTH31S04-EN

Topics: Foundation types. Design of rigid and flexibile shalow foundations (spread, pier, slab, box

foundation). Determination the bearing capacity and settlements of soils under load. Factors

effecting the value of differential settlements. Stability analysis. Types and design of different

support systems of excavations. Bearing capacity of pile foundations. Anchorages. Design of

ground anchors. Design and construction of cast in situ and prefabricated diaphragm walls.

Dewatering.

Literature:

1. Chang-Yu Ou: Deep Excavations. Taylor and Francis, London, 2006.

2. Dandy, G., Walker, D., Daniell, T., Warner, R.: Planning of Engineering Systems. Taylor

and Francis, London, 2006.

3. Fang, H. S.: Foundation Handbook. Chapman and Hall, New York, 1990.

4. Fang, Hsai, Yand, Daniels, J. B: Introductory Geotechnical Engineering. Taylor and

Francis, London, 2006.

5. Lancelotta, R.: Geotechnical Egineering. Balkema. Rotterdam, Brookfield, 1995.

6. Mitchell, J. K. Fundamentals of soil behaviour, John Wiley and Sons, New York, 1976.

7. Moseley, M. P., Kirsch, K. ed. Ground Improvement. Taylor and Francis, London, 2004.

24

8. Tomlinson, M. J.: Foundation design and construction.n. Pearson Education, Harlow,

2001.

Urban and regional development

Code: MFTEL31S03-EN



Prerequisites: None

Topics:

Urbanization. Evolution of settlements and theories. Urban sprawl. Types of settlements.

Agglomeration and conurbation. Functional role of settlements in the urban network. World

cities/global cities/mega cities. Evolution of the structure of cities. Theories of urban

development. Development strategies. Protection and reconstruction of the built environment.

Types of regions. NUTS structure of the European Union. Regional development theories.

Regional development and cohesion policies in the European Union. National Regional

Development Concept. Effects of regional development policies on urban network. European

Spatial Development Perspective.

Literature:

1. P. L. Knox, L. McCarthy (2012) Urbanization. An Introduction to Urban Geography. 3rd

Edition. Pearson Education, Glenview. ISBN 978-0-321-73643-7

2. J. Glasson and T. Marshall (2007) Regional Planning. Routledge, New York. ISBN 978-

0-415-41525-5

3. S. Sassen (2001) The Global City: New York, London, Tokyo. 2nd Edition. Princeton

University Press, Princeton. ISBN 978-0-691-07063-6

4. European Spatial Development Perspective: Towards Balanced and Sustainable

Development of the Territory of the European Union (1999) Office for Official

Publications of the European Communities, Luxembourg. ISBN 92-828-7658-6

Transportation Engineering I (Roads)

Code: MFKLE31S03-EN




Topics:

Charasteristics of road transportation. Road networks, categories. Vehicle proceeding in straight

and circular sections. Speeds, impedances. Sight distances. Horizontal and vertical alignment,

harmonization. Rural and urban intersections, sizing. Multi-level intersections. Implementing of

roads. Planning phases. Agricultural roads. Materials of road structures. Flexible and inflexible

road structures.

Transportation Engineering I (Railway Tracks)

Code: MFKLE32S03-EN




Topics: Concepts of rail transport and rail track, their particularities and elements. Kinetics and

kinematics of rail transport, its regularities. The theory and practice of track tracing, the basics of

track planning. Substructure and superstructure of the train track, its structural formation,

25

methods of estimating its bearing capacity. The theory of the rail-track without inter-space, its

conditions and regulations. Types of railway intersections, creation of track network, methods

and elements of track connection. The ageing of the track, the principles of its building and

maintenance.

Literature:

1. Dr Kerkápoly Endre: Vasútvonalak tervezése és korszerűsítése. / Planning and

Modernisation of Railway Tracks/ Tk. Bp.1968

2. Dr Gajári József: Vasútépítéstan I. II./ Railway Construction Studies I. II./ Tk. Bp. 1982

3. Dr Megyeri Jenő: Vasútépítéstan. / Railway Construction Studies/ Műegyetemi Kiadó Bp.

1997

4. Dr Kerkápoly Endre: Vasútépítéstan III. – Vágánykapcsolások. / Track Switching/

(Műegyetemi kiadó Bp. 2002)

5. Országos Közforgalmi Vasutak Pályatervezési Szabályzata 2. / Planning Regulations of

National Public Railways 2./ átdolgozott kiadás / revised edition/KÖZDOK Bp. 1993.

Building Construction I

Code: MFMAG31S04-EN



Prerequisites: MFMAB31S03-EN

Topics:

Subject of building construction science. Primary and inferior structures of buildings. Effects on

buildings, requirements. Horizontal load-bearing structures. Arches. Solid floors. Monolithic and

prefabricated RC floor structures. Frame-type buildings, architectural features. Structure of

monolithic RC frame buildings, space limiting structures. Foundation and under grade insulation.

Pitched roof: roof truss and roofing. Flat roof. Door (external and internal), window. Floor, stairs.

Chimneys and ventilation shafts. Floor finish, façade finish (envelope).

Literature:

1. Ambrose, James E. (1993) Building structures. Wiley, New York ISBN: 0471540609

2. J. Böhönyey (1986) Building construction encyclopedia. Iparterv, Budapest ISBN: -

3. Roy Chudley, Roger Greeno (2010) Building Construction Handbook. Butterworth-

Heinemann ISBN-10: 1856178056

4. Madan Mehta, Walter Scarborough, Diane Armpriest (2007) Building Construction:

Principles, Materials, and Systems. Prentice Hall ISBN-10: 0130494216


0132058812

CAD modelling

Code: MFCAD31S04-EN



Prerequisites: MFABR31X04-EN

Topics: Introduction to computer aided design. Presentation of the history of CAD. Presentation of the

screen. Giving the coordinates and drawing with coordinates. Introduction of draw (line, polygon,

circle, arch, line chain, etc.) and draw modifying commands (erase, copy, mirror, array, move,

ratate, etc.). Managing the layer and introduction of features, settings. Settings of the linetype,

http://www.google.hu/search?hl=hu&tbo=p&tbm=bks&q=inauthor:%22Roy+Chudley%22

http://www.google.hu/search?hl=hu&tbo=p&tbm=bks&q=inauthor:%22Roger+Greeno%22


http://www.google.hu/search?hl=hu&tbo=p&tbm=bks&q=inauthor:%22Walter+Scarborough%22

http://www.google.hu/search?hl=hu&tbo=p&tbm=bks&q=inauthor:%22Diane+Armpriest%22


26

context and dimension style. Usage of palettes and tools. Creating and using blocks and

references. Introduction of inqueries. Presentation of draw settings, costumizing and settings.

Detailed presentation of drop-down boxes and toolbars. Usage of model space and paper space.

Settings of printing and printing.

Compulsory/Recommended Readings:

1. www.autodesk.com

2. www.graphisoft.com

Theory of Design

Code: MFMEL31S04-EN




Topics: Principles and requirements for the safety, serviceability and durability of structures, basis of

structural design and verification, guidelines for related aspects of structural reliability according

the EUROCODE standard. Modelling of structures. Classification and modelling of general

actions on structures: self-weight, imposed loads for buildings, snow loads, wind actions, actions

on structures exposed to fire, accidental actions, seismic actions and rules for buildings, static and

dynamic action. Characteristic and other representative values of variable actions. Verification by

the partial factor method. Combinations of actions: Ultimate limit states, serviceability limit

states. Serviceability criteria.

Literature:

1. EN 1990:2002/A1:2005 Eurocode - Basis of structural design.

2. EN 1991-1-1:2002 Eurocode 1: Actions on structures - Part 1-1: General actions -

Densities, self-weight, imposed loads for buildings.

3. EN 1991-1-2:2002 Eurocode 1: Actions on structures - Part 1-2: General actions - Actions

on structures exposed to fire.

4. EN 1991-1-3:2003 Eurocode 1: Actions on structures - Part 1-3: General actions - Snow

loads

5. EN 1991-1-4:2005 Eurocode 1: Actions on structures - Part 1-4: General actions - Wind

actions


Thermal actions


Accidental actions

8. EN 1998-1:2004 Eurocode 8: Design of structures for earthquake resistance – Part 1:

General rules, seismic actions and rules for buildings

9. Basis of structural design, Guide to Interpretative Documents for Essential Requirements,

to EN 1990 and to applications use of Eurocodes; Garston, Watford, UK, 4. 2004.

Steel Structures I

Code: MFACS31S03-EN



Prerequisites: MFEPA32S03-EN, MFMEL31S04-EN

Topics:

http://www.autodesk.com/

http://www.graphisoft.com/

27

History of steel constructions. Basis of steel structures design. Mechanical properties of structural

steel: yield strength, ultimate strength, elongation at failure; ductility requirements, design values

of material coefficients. Structural analysis, elastic and plastic global analysis of structures.

Imperfections. Classification of cross sections. Resistance of cross-section: tension, compression,

bending moment, shear, bending and shear, bending and axial force, bending, shear and axial

force. Buckling resistance of members, uniform members in compression, uniform members in

bending, buckling curves. Bolted joints (shear resistance and bearing resistance), welded joints

(simplified method for design resistance of fillet weld).

Literature:

1. EN 1993-1-1:2005, Eurocode 3: Design of steel structures - Part 1-1: General rules and

rules for buildings

2. EN 1993-1-8:2005, Eurocode 3: Design of steel structures - Part 1-8: Design of joints

Timber and Masonry Structures

Code: MFFFS31S03-EN



Prerequisites: MFMEL31S04-EN

Topics: History of timber building structures: floors, roofs, walls and frames. Mechanical properties of

structural timber: yield strength, ultimate strength, elongation at failure; elastic moduli, design

values of material coefficients. Resistance of cross-section: tension, compression, bending

moment, shear, bending and shear, bending and axial force, bending, shear and axial force,

torsion. Buckling resistance of members, uniform members in compression, uniform members in

bending. Connectors for timber structures. Engineering timber structures. Mechanical properties

of masonry structures: yield strength, ultimate strength, elastic moduli, design values of material

properties. Reinforced and unreinforced masonry structures. Resistance of cross-section:

compression, bending moment, shear, bending and shear, bending and axial force, bending, shear

and axial force.

Literature:




3. MSZ EN 1995-1-1: 2010 Design of timber structures. Part 1-1: General. Common rules

and rules for buildings

4. MSZ EN 1995-1-2: 2005 Design of timber structures. Part 1-2: General. Structural fire

design.

5. MSZ EN 1996-1-1: 2009 Design of masonry structures. Part 1-1: General rules for

reinforced and unreinforced masonry structures.

6. MSZ EN 1996-2: 2006 Design of masonry structures. Part 2: Design considerations,

selection of materials and execution of masonry.

7. MSZ EN 1996-3: 2006 Design of masonry structures. Part 3: Simplified calculation

methods for unreinforced masonry structures.

8. MSZ EN 1996-1-2: 2005 Design of masonry structures. Part 1-2: General rules. Structural

fire design.



28

10. Jack Porteous & Abdy Kermani: Structural Timber Design to Eurocode 5, Blackwell

Publishing 2009, ISBN: 978-14051-4638-8

Construction Management I

Code: MFKIV31S03 -EN



Prerequisites: MFMFE31X03 -EN

Topics: Students learn about the participants of the investments in construction, they are bound to their

duties. Parts of the construction contract, together with the documents and the role of history

documents. Budget in construction, location, role, and part of the methods of calculation. The

concept of overhead hourly wage, the price of construction materials and the method of

calculation of the cost. After making a plan of complete budget should be size calculations and

shaped plans. Standard time allowance for labeling and defining technological order.

Compulsory/Recommended Readings:

1. Monori Joseph ( Ed. ) - Stephen kurty : Construction Management II . Organizing parades

. Fifth edition . Technical University Publishing House, Budapest, 1999th

2. Big Paul : Construction Technology I Technology Fund . The notes were issued in 1986,

sixth reprint . Technical University Publishing House, Budapest, 2000th

3. Consolidated Mining Issuer Collection I-II- III . TERC Budapest , 2009. , 2010. 2010th

Bridges and Structures

Code: MFMUT31S04 -EN



Prerequisites: MFGTH33S04 –EN

Topics: History of bridges. Bridge classes. Norms and preliminary works. Foundations, substructures and

equipment. Dilatations. Structure and building techniques of steel bridges. Steel beam bridges.

Steel frame, arch and suspension bridges. Orthotropic plates. Structure and building techniques of

concrete bridges. Concrete beam, frame and arch bridges. Prestressing techniques. Precast

pretensioned girder bridges. Concrete box girders. Structures and building techniques of cable-

stayed bridges. Composite and timber bridges. Test loading, monitoring and maintenance and

strengthening techniques. Reservoirs, bunkers water-towers.

Literature:

1. M. J. Ryall, G. A. R. Parke, J. E. Harding (2000): The Manual of Bridge Engineering,

Thomas Telford

2. H. G. Tyrrell (2008): History of Bridge Engineering; Stubbe Press

Theory of Girders I

Code: MFTST31SS3-EN




Topics:

29

Principle of virtual displacements and forces. Principle of potential and complementary energy.

Deflection of beams by the moment-area method and by work principle. Solution of statically

indeterminate plane structures by the force method, dead load, manual solution. Frames, trusses,

strengthened structures and continuous beams. Solution of statically indeterminate plane

structures by the displacement method, dead load, manual solution.

Literature:

1. Structural Analysis : Aslan Kassimali (2014) ISBN:1133943896

Imre KOVÁCS PhD

Theory of Girders II

Code: MFTST32SS3-EN



Prerequisites: MFTST31SS3-EN

Topics: Principle of virtual displacements and forces. Principle of potential and complementary energy.

Deflection of beams by the moment-area method and by work principle. Solution of statically

indeterminate plane structures by the force method, dead load, manual solution. Frames, trusses,

strengthened structures and continuous beams. Solution of statically indeterminate plane

structures by the displacement method, dead load, manual solution.

Literature:

1. Budynas: Advanced Strength and Applied Stress Analysis (ISBN-13: 978-0070089853)

2. Popov: Mechanics of materials (ISBN-13: 978-0135713563)

Building Construction II

Code: MFMAG32SS4-EN



Prerequisites: MFMAG31S04-EN

Lecturer: Krisztina KOZMÁNÉ SZIRTESI, Marcel FERENCZ

Topics:

Load bearing structures (walls, frames, floors, stairs, foundation). Wall-type buildings. Load

bearing and space-limiting walls. Lintel, ring-beam. Homogeneous and mixed walls. Systems of

construction and building (panels and cast wall construction, frames of reinforced concrete, steel

and wood, dry-tech construction, ready-made building). Monolithic RC walls. Partitions.

Horizontal load-bearing structures. Dense-rib, floor block, hollow ceramic block, self-

formworking floors. Comparative evaluation of alternatives. Design principles and rules of floor

systems. Balconies. Structures and roofing of pitched roof, built-in roof space. Structural variants

of wooden roof trusses. Transitional and engineered roof trusses. Steel and RC pitched roof

structures. Roof cladding. Soft sheet and plate covers. Metal structures of roof covers. Variants of

sheetmetal covers. Energy balance of buildings: components, geometric ratio and groundplan

arrangement of buildings, natural ventilation, energetic requirements, specific heat demand,

procedure of energetic design and checking.

Literature:



30






0132058812

Building Construction III

Code: MFMAG33SS4-EN



Prerequisites: MFMAG32SS4-EN

Topics:

External - independent and built-together - stairs. Structural alternatives of internal stairs. Stone

steps. Prefabricated RC, steel and wooden stairs. Accessories of stairs. Foundation and subsoil

insulation. Building constructional considerations in selecting foundation mode. Subs, protecting

and supporting structures for insulations. Insulating variants for different effects and requirements

(coating, felt, expanding and mass insulations). Flat roofs. Main functional and additional layers.

Sub, protection against wind suction. Draining vapour pressure. Plastic and coating-like

waterproofings. Utilized flat roofs. Roof terraces with conventional and elastically bedded

finishes. Variants of green roofs, functional layers. Waterproofing against functional waters.

Literature:








0132058812

Design of buildings I

Code: MFETE31SS3-EN



Prerequisites: MFMAG31S04-EN

Topics:

This course presents the functional rules of residentional building design such as dimensions of

rooms, fixtures and furnitures with their space limitations. Descriptions from OTÉK,

requirements from local development plans, specifications and calculation about forming facade.

Significance of orientation. House featuring schema – detached, semi-detached, row houses,

atriums. One and multi-storey residentional buildings. Arragements, ground plan systems and

functional rules for design of staircases. Shaping the mass, adaptions to the environment. Space

requirements for parking, garbage storage, common areas and elevators in multi-unit reaidential

buildings.

Literature:

1. Malcolm Millais: Building structures













31

2. Philip Garrison: Basic Structures for Engineers and Architects

3. Ernst Neufert : Arhitects' data

4. Jürgen Adam, Kathariana Hausmann, Frank Jüttern: Industrial Buildings

Steel Structures II

Code: MFACS32SS3-EN



Prerequisites: MFACS31S03-EN

Topics:

Uniform members in bending and axial compression. General method for lateral and lateral

torsional buckling of structural components. Uniform built-up compression members (built-up

columns with lacings and battening). Closely spaced built-up members. Design of joints,

classification of joints: classification by stiffness, classification by strength. Structural joints

connecting H or I section (single-sided beam-to-column joint, double-sided beam-to-column

joint, beam splice, column splice, column base). The component method. Design resistance of

joints with end-plate. Rotational stiffness and rotational capacity of joints.

Literature:


rules for buildings


3. Design of Steel Portal Frames for Europe, University of Edinburgh, 2011.

Steel Structures III

Code: MFACS33SS3-EN



Prerequisites: MFACS32SS3-EN

Topics:

Portal frames. Typical arrangement of portal frames. Imperfection. Load effects of frames.

Elastic and plastic global analysis of frames. Design of members (cross-section resistance,

member buckling resistance). Design of joints. Truss structures. Typical arrangement of truss

structures. Hollow section joints, types of joints in hollow section. Failure for hollow section

joints. Welded joint between CHS members. Welded joints between CHS or RHS brace

members and RHS chord members. Welded joints between CHS or RHS brace members and I or

H section chords. Welded joints between CHS or RHS brace members and channel section chord

members.

Literature:


rules for buildings


3. Design of Steel Portal Frames for Europe, University of Edinburgh, 2011.

Reinforced concrete structures II

Code: MFVBS32SS3-EN



32

Prerequisites: MFVBS31SS3-EN

Topics:

Theory of elastic slabs. Kirchhoff type slab. Loads, moments, internal forces, stresses and

deformations of elastic slab. Definition and behaviour of one way and two way slab. Design

moments of simply supported continous slabs and slab systems. Bending and torsional moments

of two way slabs, definition and determination of the main moments. Structural design of RC

slabs: determining the rreinforcement in two directions. Reinforcement for RC slabs: individual

bars and prefabricated welded mesh reinforcements. Arrangement of reinforcement in RC slabs:

detailing, anchoring, bentability of reinforcement. Structural analysis of flat slab. Detemination of

design bending moments, reaction forces and deflections by different methods. Problem of

punching shear. Design of flat slab for punching load. Detailing of punching shear reinforcement.

Plastic analysis of RC members. Definition and behaviour of plastic hinge. Static and kinematic

methods. Determination of plastic capacity, design. Plastic analysis of RC slabs.

Literature:




3. MSZ EN 1992-1-1: 2010 Design of concrete structures Part 1-1.:General rules and rules

for buildings

4. MSZ EN 1992-1-2: 2010 Design of concrete structures Part 1-2: General rules. Structural

fire design

5. MSZ 4798-1:2004 Concrete Part 1: Specification, performance production, conformity,

and rules of application of MSZ EN 206-1 in Hungary

6. Robert Park & Thomas Paulay: Reinforced Concrete Structures, Wiley-India Edition

(2010), ISBN:978-81-265-2362-5

7. Prab Bhatt, Thomas J. MacGinley & Ban Seng Choo: Reinforced Concrete Design Theory

and Examples,Taylor & FrancisGroup (2010), ISBN: 0-415-30796-1

Reinforced concrete structures III

Code: MFVBS33SS3-EN



Prerequisites: MFVBS32SS3-EN

Topics:

Torsion of RC cross sections. Effect of normal force. Buckling of RC column. Normal force –

Bending moment interaction, interaction curve and interaction surface. Structural design of RC

columns, analysis of braced and unbraced members. Determination of the excentricities,

imperfections, second order effects, design value of bending moments. Analysis of RC frames,

design of D regions by strut models: corbels, corners, etc., reinforcing details. Prestressing of RC

sections, technologies and design. Reinforced concrete walls and shearwalls. RC walls as the

member of the bracing system. Reinforcing details of RC walls. RC foundations, design of flat or

slab foundation, design of RC piles. Problems, technologies and reinforcing details of industrial

floors. Application of steel fibre reinforcement.

Literature:




33


for buildings


fire design




(2010), ISBN:978-81-265-2362-5



Geotechnics IV

Code: MFGTH34SS3-EN



Prerequisites: MFGTH32S04-EN, MFGTH33S04 -EN

Topics: History of deep foundation. Load bearing capacity of foundations. Effect of the surrounding

soil/rock. Load transmitting systems. Piling techniques, examples. Designing of piles and pile

groups. Building and designing of diaphragm walls. Diaphragm wall boxes. Design aspects of

underground garages. Underpasses. Mechanized and conventional tunnelling. Pipe bursting.

Lining materials and techniques of underground structures. Soil improvements.

Literature:

1. Károly Széchy (1966): The art of tunnelling, Akadémiai Kiadó

2. Utsav Chandra Kalita (2011): Soil Mechanics & Foundation Engineering, PHI Learning

Pvt. Ltd

3. Sahashi K. Gulhati, Sahashi K Gulhati Manoj Datta (2005): Geotechnical Engineering,

Tata McGraw-Hill Education

Construction Management II

Code: MFKIV32SS3 -EN



Prerequisites: MFKIV31S03 -EN

Topics: Create a budget based on the total of the previous semester band prepared schedule, making

machine schedule, preparation of staff schedules.

Creating organizational layout in three phases. Substructure works, structural work and during the

final phase of work. . Learn the temporary structures, temporary utilities, roads and means of

disposal solutions and marking of installed equipment.

Efforts should be made to both the installation and closed freely available land can plan!

Literature:

1. Monori Joseph ( Ed. ) - Stephen kurty : Construction Management II . Organizing parades

. Fifth edition . Technical University Publishing House, Budapest, 1999th

2. Big Paul : Construction Technology I Technology Fund . The notes were issued in 1986,

sixth reprint . Technical University Publishing House, Budapest, 2000th

3. Consolidated Mining Issuer Collection I-II- III . TERC Budapest , 2009. , 2010. 2010th

34

FEM modellnig I

Code: MFVEM31SS3-EN



Prerequisites: MFACS32SS3-EN, MFVBS32SS3-EN, MFTST31SS3-EN

Topics:

The basis of the Finite Element Method (fundamentals of elasticity, the basic ideas of FEM).

Mathematical computational and mechanical background. Overview on the frequently used types

of elements in the structural analysis. Approximate calculations (Lagrange variational principle,

Ritz method). Compatible element model. Elemental and structural matrices. Isoparametric finite

elements. Computation of planar beam structures. Modelling questions. Contact problems.

Modelling of beams with the use of different elements. Modelling of frame structures. Modelling

of trusses. Modelling of structural joints. Modelling of concrete slabs. Modelling of concrete

pools. Modelling of timber structures.

Literature:

1. Bathe, K. J. (1982): Finite element procedures in engineering analysis, Prentice-Hall, Inc.,

Englewood Cliffs, New Jersey 07632, 1982.

2. Bathe, K.J. (1991): Finite Element Procedures, Prentice-Hall, Inc., New Jersey, 1996.

3. Szabó, B. Babuska,I. (1991): Finite Element Analysis, John Wiley & Sons Inc., New

York, 1991.

4. O. C. Zienkiewicz, Robert Leroy Taylor (2000): The Finite Element Method: Solid

Mechanics, Butterworth-Heinemann, ISBN 0750650559, 9780750650557

5. O. C. Zienkiewicz, Robert Leroy Taylor, J. Z. Zhu, Perumal Nithiarasu (2005): The Finite

Element Method: Its Basis and Fundamentals, Butterworth-Heinemann, 2005, ISBN

0750663200, 9780750663205

6. I. Bojtár, Zs. Gáspár The finite element method – the basis

7. Guides of the FEM programs

Subjects of Structural Architect Specification

Steel buildings

Code: MFMAC31SM3-EN



Prerequisites: MFACS33SS3-EN

Topics:

Steel buildings. Steel frames with simple (nominally pinned) joints. Steel frames with semi-rigid

joints. Steel frames with rigid joints. Basic and practice of the modern theory of design.

Connections of steel structures and the frame structures. Design of multi-storey steel buildings:

approximate calculation, detailed calculation (loads, calculation of the stresses, examination of

the structural elements, sizing of the connections).

Literature:


rules for buildings


1. Design of Steel Portal Frames for Europe, University of Edinburgh, 2011

35

2. Eurocode-Manual: Design of multi-storey steel buildings, Miklós Iványi, Péter Iványi,

Pollack Press, 2008.

Reinforced concrete buildings

Code: MFMVB31SM3-EN



Prerequisites: MFVBS33SS3

Topics:

Reinforced concrete buildings. Monolitic and prefabricated systems: structural elements of RC

frames and RC halls. Bracing systems of tall buildings. Reinforced concrete constructions:

forming of dilatations, forming of structural joints, structural elements for thermal, voice and

water isolations as well as vibrations, connection of prefabriacated RC members. Special design

problems of construction of prefabticated elements: connections of monolithic and prefabricated

element, detail of joints. Design considerations for the main formwork types. Effect of fire on RC

structures, structural fire design.

Literature:





for buildings


fire design




(2010), ISBN:978-81-265-2362-5



Composite structures

Code: MFMOS31SM3-EN



Prerequisites: MFACS32SS3-EN, MFVBS32SS3-EN

Topics:

Basic problems of composite structure in general. Behaviour of an inhomogen cross-section,

stresses and deformations. Effect of material properties: creep and shreankeage of concrete.

Materials of steel-concrete composite building structures. Mechanism of force transferring

between components. Type of connectors. Elastic calculation of composite beams. Plastic

calculation of composite beams. Design of composite columns. Design of slabs with trapezoidal

sheet.

Literature:

1. EN 1990:2002/A1: 2005 Eurocode 1 - Basis of structural design.

2. EN 1991-1-1: 2002 Eurocode 1: Actions on structures - Part 1-1: General actions -


36

3. EN 1994-1-1: 2010 Design of composite structures – Part 1-1: General rules

Engineering timber structures

Code: MFMFS31SM3-EN



Prerequisites: MFFFS31S03-EN

Lecturer: Beáta SZAKÁCS, Imre KOVÁCS PhD

Topics:

Timber as a structural material: strength and elastic properties. Engineering wood products.

Designof members subjected to flexure. Deign of members and walls subjected to axial or

combined axial and flexural actions. Design of glued laminated members. Design of composite

timbr and wood-based sections. Design of buil-up columns. Design of stability bracing, floor and

wall diaphragms. Design of metal dowel type connections. Design of joints with connectors.

Moment capacity of connections formed with metal dowel fasteners or connectors.

Literature:




3. MSZ EN 1995-1-1: 2010 Design of timber structures. Part 1-1: General. Common rules

and rules for buildings

4. MSZ EN 1995-1-2: 2005 Design of timber structures. Part 1-2: General. Structural fire

design.



6. Jack Porteous & Abdy Kermani: Structural Timber Design to Eurocode 5, Blackwell

Publishing 2009, ISBN: 978-14051-4638-8

Streightening of structures

Code: MFSZM31SM3-EN



Prerequisites: MFACS33SS3-EN, MFVBS33SS3-

Topics:

General rules and methods for diagnostic and qualification of load-bearing structures. Rules and

methods for strengthening of structures. Strengthening of concrete beams. Strengthening of steel

frames. Strengthening of joints of steel frames. Strengthening of timber structures. Construction

of wall openings.

Literature:

1. K.Koris, I.Bódi: Strengthening of structures

Design of buildings II

Code: MFETE32SM3-EN



Prerequisites: MFETE31SS3-EN

37

Topics:

This course presents the design methodology of industrial and agricultural buildings. Functional

rules of industrial and agricultural buildings by OTÉK, limitations about peripherial built-in

areas, local development plans, main elements, structures. Specific technology requirements

descriced by animal species. Health and environmental rules. Manure management. Structures

and types of storage buildings and plant productions. Industrial parks and their regulations,

standards. Logistics and service facility needs. Structures of industrial buildings, particularly in

light weight structures. Design of social and service spaces, lockers and wet rooms. Fire

protections: Basic rules, structures and classification of buildings based on OTSZ.

Literature:

1. Malcolm Millais: Building structures

2. Philip Garrison: Basic Structures for Engineers and Architects

3. Ernst Neufert : Arhitects' data

4. Jürgen Adam, Kathariana Hausmann, Frank Jüttern: Industrial Buildings

Diploma project

Code: MFSZA31SS15-EN



Prerequisites: MFACS33SS3-EN, MFVBS33SS3-EN

Geoinformatics laboratory

Code: MFGIG31S00-EN

Classes/week: 1 week



Industrial practice

Code: MFTEG31S00-EN



Prerequisites: None

Structural engineering geoinformatics laboratory

Code: MFSGG31SS0-EN



Prerequisites: MFGIN32S04-EN, MFGIG31S00-EN

Material and structural engineering laboratory

Code: MFAMG31SS0-EN



Prerequisites: MFEPA32S03-EN, MFACS32SS3-EN, MFVBS32SS3-EN

Objective of the internship, competences ·

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Students get acquainted with professional work in conformity with their specialist at a company

or institution and join in the daily working process. They have to resolve tasks independently

assigned by their supervisor and gain experiences may be utilized later in the labour market.

During the internship common and professional competences may be acquired. Common

competences: to precise working on schedule either individually or in team, to take part in talking

shops applying correct technical terms. Professional competences: applying professional skills

gained during the training and acquiring new knowledge.

Places suitable for internship

All the organizations, institutions and companies, provide students with the opportunity to

acquire proficiency in accordance with their specialization in the field of operation, repairing

technology, installation, management and development of different machines and vehicles, may

be a suitable place.

Documents necessary for commencing and completing the internship

The numbers of document copies is equivalent with the number of signers. The document types

which must be signed are here: Invitation Letter, Internship Cooperation, “Megállapodás”

(Company in Hungary), Student Agreement (Company abroad) The submission deadline is May

2016 to secretariat (Ms. Nóra Tóth, room 120).

Evaluation Sheet and Certificate must be submitted till September 2016 to Ms. Nóra Tóth.

Initiative of the internship at the company and providing for the documents from the company is

the student’s duty. If the student doesn’t specify the receiving company or doesn’t provide for the

Invitation Letter or the initiative of the Agreement and the Student Agreement (or its signature) in

time, the specialist responsible will refuse the Internship Certificate.

Execution of the Internship and its certification

1. The duration of the internship is 6 weeks.

2. Besides completing the internship, students have to compile a 15-20 pages essay about the

work done. The topic of the essay must be negotiated with the supervisor and attached to the

activity actually done by the student. It is expedient to choose a topic which may be appropriate

either for participating in the National Scientific Students' Associations Conference ("OTDK") or

a thesis.

3. The execution of the internship must be certified by the Evaluation Sheet and Certificate form

can be downloaded from the website of the Department of Civil Engineering. The deadline of

submitting the Essay and the “Evaluation Sheet and Certificate”: September 2017, office 212

(Ms. Eva Hadházi Volszkyné) Summary of the tasks and deadlines regarding the internship

the student sign up for the Internship course via the NEPTUN in the spring semester,

contact the company and provide for the Invitation Letter (1 copy) must be submitted to

the secretariat, for the Internship Cooperation (2 original copies, company is abroad) or

““Internship Cooperation with Company in Hungary”” (4 original copies, company is in

Hungary) and for the Student Agreement (3 original copies) respectively signed by the

company till May 2017. Please remember that it is the student’s responsibility to meet the

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deadline given! Having the documents signed by the Dean of the Faculty and sending

copies to the company by post is the duty of the secretariat.

executing the 4 weeks internship in the summertime,

providing for the Evaluation Sheet and Certificate form at the end of the internship and

submitting it together with the essay to Dr. Imre Kovács responsible for the internship

program at the department till September 2017.

Exemption

A partial exemption may be required by the student who has completed an internship in the

secondary school and it is certified by the secondary school certificate. The request for partial

exemption can be submitted till May 2017. After this deadline requests are denied. The copy of

the secondary school certificate and the written request addressed to Dr. Imre Kovács specialist

responsible must be submitted to Ms. Eva Hadházi Volszkyné secretary (office 212). In case of

any problem arising from the internship please contact Dr. Imre Kovács head of the Department

of Civil Engineering (office 212, [email protected]) or Ms. Eva Hadházi Volszkyné secretary

(office 212, [email protected]).

FACULTY BACKGROUND, AND HISTORICAL FACTS

The history of the Faculty of Engineering dates back to 1965, when the Technical College was

established. In 1972 it was named Ybl Miklós Polytechnic and in 1995 it became part of Kossuth

Lajos University. In 2000 the Faculty of Engineering became part of the integrated University of

Debrecen.

In 2005 the Bologna System was introduced, which aids the compatibility of the qualifications

received at the University of Debrecen with universities all over Europe.

The Faculty of Engineering is at the forefront of education and training of engineers in the North

Great Plain Region and in the whole of Hungary. It is a dynamically developing Faculty with

over 3.000 students and a highly-qualified and enthusiastic teaching staff of about 80 members.

The teaching staff is involved in numerous domestic and international research and design

projects. The Faculty of Engineering is practice oriented and develops skills required for the

current conditions of the national and international labor market. The recently opened new

building wing with its ultra-modern design hosts several lecture halls, seminar rooms and

laboratories equipped with the latest technology. Our students are provided with practical

knowledge, training and field practice with the help of the numerous prestigious domestic and

multi-national industry partners. The internship periods are excellent opportunities for students to

experience theory put into practice at the most renowned industry representatives and to become

more successful in the labor market in this highly competitive sector. Students learn to operate in

the working environment of multi-national companies and adapt to challenges easily. After

graduation they will be able to operate at a strategic decision-making level, placing priority on

efficiency and engineering ethics.

The Faculty of Engineering offers a great variety of BSc, MSc courses and post-graduate training

courses tailored to suit the rapidly changing world of engineering and focusing on European and

international trends. In order to optimize the quality of training, the Faculty continuously strives

to expand the number of industrial and educational partners at home and abroad.

The Faculty of Engineering launched the engineering trainings in English in 2011.

The Faculty of Engineering has been a pioneer in the introduction of the Quality Management

System at faculty level to measure and evaluate the efficiency of its education and teaching staff

in order to improve the quality of education and training from the feedback received. The Faculty

was awarded by the Ministry of Education the Quality Prize in 2011 as recognition of its efforts

in this field.

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The Faculty of Engineering has a vivid student life. There is a film club waiting for movie buffs

and the door of the Faculty library is always open. The library is not only the host of the most

recent technical books, exhibitions and tea afternoons with invited speakers, but students can also

purchase theatre and concert tickets here from the staff. The Borsos József dormitory is also a

hub of activities for students.

The increasing number of foreign students brings cultural and ethnic diversity to the faculty.

Our aim is to aid students to become efficient members of the labor market and enrich the world

of engineering in Hungary and abroad with their knowledge and expertise.

FACILITIES AND INFRASTUCTURE OF THE TRAINING

Classrooms, auditoriums, laboratories and their instrumentation, workshops.

The available capacity of the lecture halls:

24 classrooms and drawing-rooms for

training purposes (each with 16-70 seats,

altogether 1.258 seats, measures 1.670 m2)

18 auditoriums (each with 78-256 seats,

altogether 1.281 seats, measures 1.396 m2)

The total capacity of full-time students:

3.250. Current number of students:

approximately 2.860.

IT, Teaching technology and library supply etc.

3 IT

laboratories

for teaching

graphics and

CAD, seating

30 people each.

The Faculty library is a unit of the University and

National Library of Debrecen University. The

Library lays special emphasis on the extension of

its electronic services. Most units of the Library

worked with the integrated library system of

Corvina (former Voyager) since 1992. The Library

attaches great importance to collecting modern in-

formation carriers beside the traditional printed

documents. Either by being a member of national consortia or by local subscription the library

ensures that the citizens of the University be able to search in the bibliographic and full-text

databases of the most important scientific periodicals of each discipline (EBSCO, WEB of

Science, Elsevier periodicals, Biological Abstract, PsycINFO, Jstor etc.) It collects processes and

services the specialized literature of the taught and researched fields of the sciences. It stores

about 40,000 specialized books, textbooks and notes, 140 Hungarian and 25 foreign specialized

journals, thousands of standards, extra materials for teaching and planning, product catalogues

and brochures.

Language learning materials

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The library provides students with language books, CDs and cassettes which help students fulfill

the foreign language requirements necessary to finish the major. It pertains to the Hungarian

teaching materials too in the case of training foreign students.

Different services and benefits which help students graduate

Learning tools (course books and notes, technical books in Hungarian and in English)

Textbook store where students can use their financial aid allocated for notes/textbooks

Free wireless internet access in the Faculty buildings, including the dormitory

Administration unit

There is a Registry at the faculty, administration of courses is fully electronic with the NEPTUN

system, the retrieval is helped by a register system.

LABORATORIES

Laboratory and tutorial workshop background of the Mechanical Engineering and

Mechatronics Engineering fields

o Biomechanical materials testing lab: for testing prosthesis’, plastics’ and light metals’

joints. Applied equipment: INSTRON 8874 universal biaxial materials testing machine.

o LabView teaching room: The basic teaching of LabView is carried out by 8 colleges

trained by National Instruments (NI), in the teaching room supplied with 40 PCs. This

lab is equipped with the latest technology of NI.

o LEGO MINDSTORM teaching room: Thanks to LEGO Hungary, 8 pieces of LEGO

MINDSTORM robots are available for teaching the basics of the robot actuation and

sensing technologies.

o Machine elements lab: oscilloscope, photo elastic bench, Spider 8 amplifier, DMC

9012 amplifier, CATMAN evaluating software, force transducer, torque transducer,

inductive displacement transmitter, test pads.

o Machining shop: 5 machine lathes, 2 milling machines, gear-cutting machines,

generating milling cutters, centre grinder, web-framed cross-cut saw, EMCO PC Mill

type CNC drilling machine, CKE 6136i type CNC turning machine.

o Material testing lab: OLYMPUS GX41, NEOPHOT-2 and EPIGNOST-2 type metal

microscopes.

o Machine repairing lab: hand tools, turning lathe, Castolin ROTOTEC type flame

spraying pistol, EUTALLOY Super Jet type flame spraying pistol, column-type drilling

machine.

o Measuring lab: calliper gauge, micrometer calliper gauge, base tangent length

micrometer, optical dividing head.

o Mechanical technology lab: tensile-testing machine, ZD 20 type hardness tester,

impact-tester, Brinell microscope, fatigue-testing machine.

o Metallographic lab: NEOPHOT type 2 and EPIGNOST type 2 microscopes, grinding-

and polishing machines, power supply and auxiliary tools for electrolytic etching

o SKF and diagnostics lab: manual OILCHECK equipment, CMVP type 10 vibrometer

pen, CMVP type 30 SEE pen, shock impulse analyzer with PRO32-2 and PRO46-2

software, Testo 816 type acoustimeter, infrared distance thermometer, UNIBALANCE 4

type balancing equipment, informatics background

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o X-Ray lab: MXR type equipment, Liliput type radiation source, VA-J-15 type radiation-

measuring assembly, densitometer, processing gauge, radiographic materials testing,

magnetic crack detection, ultrasonic testing, liquid-penetrant testing.

o Welding workshop: 8 gas welder workstations, 6 manual arc welding workstations, 3

consumable-electrode welding workstations, 3 argon-shielded tungsten-arc welding

workstations.

o ZF Lenksysteme Hungary Automotive Laboratory: the laboratory is equipped with

ZF Lenksysteme Hungary’s products, mountable steering systems and steering columns

Laboratories of the Building Mechatronics Research Center

o Building mechatronics research laboratory: The purpose of the laboratory is the

elaboration of methods to carry out intelligent evaluation of measurements, intervention

and planning. The competence of the laboratory includes the integrated parts of building

automation, building supervision and security techniques, including the operation of

necessary sensors, regulators and interveners, which is defined as building mechatronics.

o Hydraulics laboratory: Presentation of most modern hydraulic systems and research in

the field of hydraulics, teaching of hydraulic subject-matters on the basis of the

programs elaborated by FESTO Ltd. Didactic, resp. BOSCH-Rexroth. The laboratory

has been set up and is sponsored by BOSCH-Rexroth Ltd. and FESTO Didactic Ltd.

o Laboratory of electronic engineering and electronics (Rohde & Schwarz reference

lab): The main competence of the laboratory is the measuring of electric quantities in

the field of mechatronics, mechanical engineering and chemical mechanical engineering

by means of digital and analogue circuits. There are 10 measuring stations in the

laboratory, which means that 20 students can carry out measurements at the same time.

o Laboratory of re-configurable mechatronics controllers: The purpose of the

laboratory is the research and further development of intelligent controllers by using

freely configurable digital electronic tools.

o Measurement and Control Engineering Laboratory: The following tools are of

cardinal importance in the laboratory for the support of teaching and research activities:

- storing oscilloscope

- power-supply unit

- digital manual instruments

- plotter

- function generator

- data collection and signal conditioning unit

o MPS manufacturing line laboratory: Teaching of pneumatics on the basis of the

program elaborated by FESTO Ltd. Didactic in the field of pneumatics, electro-

pneumatics, hydraulics, electro-hydraulics, PLC technique, driving technique,

mechatronics and sensor technique.

o MPS PA laboratory: Presentation and research processes based on the flow of

industrial liquids. Study and research of the control of closed and opened systems. Festo

Didactic’s Learning System for process automation and technology is orientated towards

different training and educational requirements.

o NI Elvis (Educational Laboratory Virtual Instrumentation Suite) Lab: The NI

Educational Laboratory Virtual Instrumentation Suite (NI ELVIS) features an integrated

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suite of 12 of the most commonly used instruments in the lab - including the

oscilloscope, digital multimeter, function generator, variable power supply, and Bode

analyzer - in a compact form factor for the lab or classroom demonstrations. Based on

NI LabVIEW graphical system design software, NI ELVIS, with USB plug-and-play

capabilities, offers the flexibility of virtual instrumentation and allows for quick and

easy measurement acquisition and display.

o Pneumatics laboratory (FESTO FACT -Festo Authorized and Certified Training

Center): Teaching of pneumatics on the basis of didactic programs of FESTO Ltd. In

the field of pneumatics, electro-pneumatics, hydraulics, electro-hydraulics, PLC

technique, driving technique, mechatronics and sensor technique.

o Robotics laboratory: The lab contains 16 workstations of robot technology, allowing

32 students to work simultaneously. There are altogether 16 PLC controlled robots at the

16 workstations.

o Schneider Electric knowledge center: all teaching, research, expert and advisory

activities concerning the products of Schneider Electric and the examination of the

possibility of their non-conventional use. The laboratory is suitable for the following

activities:

- Teaching of industrial controls by means of small and medium PLCs and realization

of real industrial processes on twido demonstration tables built with PLCs of type

M340.

- Regulation of driving technical models by programming frequency changers

(ATV11, ATV31 and ATV71).

- Complex engineering tasks by connecting operating models into the network.

IT laboratories and software

AutoCAD® Map 3D

AutoCAD®2010

Solid Edge

FEMAP v9.3

Autodesk® Inventor®

AutoCAD® Electrical

Autodesk® Robot™

ECOTECT

LabVIEW

RobotStudio

Fanuc Oi MATE TC Control

Air and Noise Protection Laboratory

Purpose of the laboratory

The Air and Noise Protection Laboratory provides the practical background for different courses

such as Noise and Vibration Protection, Air Quality Protection, and Unit Operations. Numerous

different specific software are introduced to students in the lab, which is also the place for result

processing of field measurements.

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Competence of the laboratory

The laboratory is suitable for carrying out and post-processing acoustic and vibration diagnostic

tests. In addition, modeling noise and air pollution propagation and noise mapping are also

important tasks of the lab, just like mathematical modeling of dynamical systems in the field of

chemical and environmental methods. Numerous software are used for the determination of

optimal operation of chemical and environmental systems.

Our partners

DKV Debrecen Transportation Services Ltd., Plánum 97 Ltd., TIKTVF (Green Authority)

Equipment in the laboratory

The laboratory boasts 20 personal computer with software for modeling noise and vibration

measurements (IMMI, SAMURAI) and environmental processes (MATLAB, Control System

Toolbox, Simulink Toolbox). The laboratory is also equipped with measurement systems and

devices for in situ tests, such as a Soundbook universal multi-channel acoustic measuring system,

four channel analyzers with Samurai software for vibration and noise measurements, a PDV 100

portable digital vibrometer, SINUS 3D seismometer and a Larson Davis 831 sound level meter.

Additionally, other sound level meters are available for student measurements.

Cutting and CNC Workshop


The laboratory is based on the common and latest production technologies, thanks to which

students have the opportunity to see the material removal processes on the production machine in

real time. The machinery and equipment used in the lab provide the scientific and technical

background to education. The available technologies are identical with the latest technologies

used in industry.


Students learn about the basic manufacturing procedures (lathe machining, milling, planning,

sawing, grinding gear-tooth forming), the main parts of the equipment and their operation by

working on the machines in small groups. They also have the opportunity to study the cutting

edge geometry of the different tools.

Our partners

Optimum Hungary Ltd


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The workshop is equipped with five universal lathe machines, a universal milling machine with

two planer machines each, a Fellow Gear machine, two saw machines, two grinding machines

used to sharpen tools.

A type of OPTI M2 CNC milling machine, a CNC lathe L28 Opti and Opti D280x700 a type

universal lathe.

CNC programming and simulation software are available for ten students.

Diagnostics Lab


The purpose of the lab is to provide the technical background to different diagnostic tests and

measurements applied in general mechanical engineering. Studying the application of measuring

systems and special diagnostic devices is also emphasized in the lab. Students can practise how to

set up and carry out measurements and draw the conclusion about technical problems.


Acquiring the basics of measurement techniques of machine fault diagnostics applied in machine

repairing and maintenance engineering fields. With the up-to-date equipment and measuring

systems students carry out different testing and structural analysis of structures and machine

elements as research and scientific activities. Our lab also provides the scientific and technical

background for PhD students.

Our partners

SKF Group, FAG Schaeffler Technologies AG & Co. KG · Deutschland,

GRIMAS Hungary Ltd., SPM Instrument Budapest Ltd., KE-TECH Ltd.


The following measurement devices are available:

Oilcheck oil tester

CMVP 10 vibration tester

CMVP 30 SEE tester

SPM analysator with PRO32-2 and PRO46-2 software’s

VIB 10 vibrometer

Testo 816 noise meter

Center 320 noise meter

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Infrared thermal meter

SPM Leonova Infinity universal vibration tester

SPM Vibchecker

SPM Bearingchecker

Flir (ThermaCAM E45)

Labview software

Audacity acoustic software

Building mechatronics research laboratory


The goal of the laboratory is the elaboration of methods for carrying out intelligent evaluation of

measurements, intervention and planning. The international research carried out in the laboratory

promotes the activity of practicing planners, operators and builders so that they can use more

efficient building engineering and building supervision systems from an energetic aspect and for

buildings to meet the comfort feeling of residents, especially their special requirements in case

environmental conditions differ from normal circumstances.


The competence of the laboratory includes the integrated parts of building automation, building

supervision and security techniques, including the operation of necessary sensors, regulators and

interveners, which is defined as building mechatronics. Our researchers have a wide-ranging

theoretical and practical experience in automation of building engineering systems of intelligent

grounds, elaboration of their support by means of building information technology as well as

elaboration of objectives relating to the cost-saving intelligent automation of systems.

Our partners

The laboratory was established thanks to the EU-funded project “HURO/0802/155_AFA

„Hungarian-Rumanian Research and Development Platform for supporting the building of

Intelligent Buildings” and with the co-operation of the European Regional Development Fund.

Apparatus utilizing renewable energy were built with the co-operation of ENERGOTEST Ltd,

while the measuring and automations objectives have been realized by means of instruments and

software of National Instruments.


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The construction and embodiment of the apparatus manufactured individually and installed into

the laboratory promotes the access for teaching, research, presentation and measurement.

Hot water supply system

Vacuum-tube solar collector (1000W).

Flat solar collectors:

Buffer stores

6 pcs solar cells (PV) to be used for research.

Rotating stand

Biomechanics Laboratory


The main purpose of the lab is the determination of mechanical properties of polymer structural

materials and biomaterials in contrast with stress. The Laboratory of Biomechanics participates in

material testing, particularly in tests of human bones. The Laboratory supports the following

courses: Biomechanics, Material Testing Methods of Plastics and CAD-CAM, Rapid

Prototyping. It is also used for various research activities.


The Biomechanical Material Testing Laboratory was founded in 2005 for accredited material

testing activities with its quality management system. The main activity of the Material Testing

Laboratory is research: various biomechanical nature experiments, measurements and tests. In

accordance with the accredited activity orders from external companies are executed as well.

Our partner

DEKK (University of Debrecen, Clinical Center)


The most important devices of the laboratory:

Instron 8874 biaxial material testing machine,

Instron AVE advanced video extensometer,

Instron 51 portable digital durometer,

Mitutoyo measuring devices,

Torque meters,

Connex three dimensional printer

Zprinter 310 three dimensional printer,

Cobra Fastscan three dimensional scanner.

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Heat Treatment Lab


Heat treating is a group of industrial and metalworking processes used to alter the physical, and

sometimes chemical, properties of a material. The following basic heat treatment techniques take

place in the laboratory: annealing, case hardening, precipitation strengthening, tempering and

quenching processes for small groups (8-10 students).


The lab supports the teaching of the Materials Sciences and Manufacturing Engineering practice

course, and presents the main heat treatment processes for small groups (8-10 people). With the

up-to-date equipment and heat treatment techniques different heat treatment methods of different

materials can be carried out as research and scientific activities.


Heat treatment furnaces: RE-60, KO-14, ET-2

Quenching vessels: water, oil, salt

Hardness testers

Temperature measurement & management equipment

Personal protection & safety equipment

Machine Elements Lab


The machine elements lab practice is part of the Machine Elements course, which introduces

machine elements and machine constructions built up of them to students, familiarizing them

with the material taught at lectures. Machines and equipment in the lab are designed in the

framework of the four designing tasks: Welded Machinery Base; Hydraulic Cylinder; External

Double-Shoe Thruster Released Drum Brake; Counter drive, which may be dismantled and

assembled with the guidance of the instructor.


http://en.wikipedia.org/wiki/Industrial_process

http://en.wikipedia.org/wiki/Metalworking

http://en.wikipedia.org/wiki/Physical_property

http://en.wikipedia.org/wiki/Chemical_property

http://en.wikipedia.org/wiki/Annealing_%28metallurgy%29

http://en.wikipedia.org/wiki/Case_hardening

http://en.wikipedia.org/wiki/Precipitation_strengthening

http://en.wikipedia.org/wiki/Tempering_%28metallurgy%29

http://en.wikipedia.org/wiki/Quench

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Students have the opportunity to gain hands-on experience with machine elements and parts and

to study their construction and operation methods. The lab provides the background for the

technical knowledge and hands-on skills required by the educational and outcome requirements

of the training program. Students have the opportunity to design the four designing tasks, operate

and maintain mechanical systems. The lab is equipped with test-benches instrumented with an

up-to-date measuring system comprising an amplifier and evaluating software, which is suitable

for the fast, electrical measurement of mechanical parameters changing with time.

Our partner

Hottinger Baldwin Messtechnic Ltd. (HBM)


Test benches for testing drive train vibration, bolted joints, spring operation, endurance limit of

composite materials and friction phenomenon between surfaces, and so on.

The lab is instrumented with Spider 8 amplifier and CATMAN Easy software from HBM for

acquisition and evaluation of the measurement signals provided by transducers for the

measurement of force, pressure, acceleration, torque, and displacement. The Catman software

package running under MS-Windows is applied for experimental stress analysis with strain

gauges and an on-line measurement system.

The applied transducers and gauges:

force transducers: measure static and dynamic tensile and compressive loads,

torque transducers: in rotating and non-rotating version,

pressure transducers: for absolute and differential pressure measurements,

displacement transducers,

strain gauges for determining the strain on the surface of components,

piezoelectric accelerometer.

Hydraulics laboratory


Presentation of most modern hydraulic systems and research in the field of hydraulics.


Teaching of hydraulic systems of different courses by means of software developed by FESTO

Didactic Ltd, resp. BOSCH-Rexroth.

Our partners

The laboratory is sponsored by BOSCH-Rexroth Ltd and FESTO Didactic Ltd.

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Two-side stand system with hydraulic power-supply unit, slave cylinder, hose storage, oil

tray, hydro-battery, cog-wheel motor, pressure limiter, stuffing-one-way valves,

electronically controlled root changers, manometers,

error locating system: electro-hydraulic elements operating defectively, manually controlled

valves operating defectively,

a set of mobile hydraulic elements, including the control block necessary for mobile

hydraulic research,

axial-piston hydro-motor, pre-controlling apparatus and loading simulator.

Laboratory of electronic engineering and electronics


In the laboratory students obtain experience in the field of electronics and electronic engineering

in the framework of the following courses: electrical engineering and electronics, technique and

electronics and chemical science of mechanics.


Students measure electric quantities by means of digital and analogue circuits composed by the

students themselves, which enables them to extend their experience. The examination of passive

and active elements for understanding the operation of digital and analogue circuits is also

possible, just as well as practising the search of electric errors. The laboratory takes part in the

development of electric cars through activities such as the energy supply of vehicles, charging

batteries, planning and building dashboard panels.


There are 10 measuring stations in the laboratory, where 20 students can carry out measurements

at the same time. The equipment of the stations includes 2-channel and 35-MHz oscilloscopes, 2-

MHz function, direct-current double power-supply units, 3,5-digit multimeters, and measuring

bags.

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Mechanical Lab


The laboratory is based on common testing methods of raw materials, technological materials and

structures like welded joints. The devices in the lab follow the order of an ordinary material

testing method. There are several devices for test sample preparation (cutting, grinding).

Comprehensive analysis of materials is rendered possible by the tensile test machine and the

Charpy impact testers.


Transferring the basic knowledge of lectures of material testing, technology of structural

materials, fracture mechanics courses, representing the testing processes by specialized test

machines. Our lab is a scientific and technical background for PhD students providing the

facilities to carry out experimental tests for research and scientific activities.


Tensile test machine (with computer managed closed loop data storage & handling)

Charpy impact tester machines (computer controlled from 0 to 450J impac5t range)

Hardness tester (computer managed)

Furnace up to 1300°C (computer managed heating & cooling curve)

Personal protection & safety equipment

MPS PA laboratory


Presentation and research processes based on the flow of industrial liquids,

study and research of the control of closed and open systems,

FESTO Didactic’s Learning System for process automation and technology is orientated

towards different training and educational requirements.

52


Teaching of pneumatics on the basis of didactic programs by FESTO Ltd. in the fields of

pneumatics, electro-pneumatics, hydraulics, electro-hydraulics, PLC technique, driving

technique, mechatronics and sensor technique.

The systems and stations of the modular Production System for Process Automation (MPS® PA)

facilitate vocational and further training in line with industrial practice. The actual project phases

can be taught in training projects which include: planning, assembly, programming,

commissioning, operation, optimisation of control parameters, maintenance and fault finding.

Our partners

The laboratory was established within the framework of the project TÁMOP-4.1.1/A-10/1-

KONV-2010-0016 and supported by FESTO Ltd Didactic.


instrumentation for measuring and evaluation of quality and technological data of filtering,

mixing, reactor, charging (bottling), thermo and hydrodynamic measurements, control with

opened and closed cycle,

filtration, mixing, reactor station and bottling station.

MPS Manufacturing Line Laboratory


Teaching and research of industrial discrete processes;

study and research of the control of closed and open systems.


Teaching of pneumatics on the basis of the program developed by FESTO Didactic Ltd. in the

field of pneumatics, electro-pneumatics, hydraulics, electro-hydraulics, PLC technique, driving

technique, mechatronics and sensor technique. The laboratory carries out research on the basis of

contracts signed with FESTO Didactic Ltd.

Our partners

The laboratory is sponsored by FESTO Didactic Ltd.


a 5-cation manufacturing line built by FESTO Didactic Ltd.

software programming of the production schedule, examination of the advance and

automated quality monitoring between actions of the manufacturing

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NI ELVIS laboratory


The aim is to provide practical courses in basic electrotechnics and electronics, and to grant

specialized knowledge and experience to mechatronics students in special areas like data

acquisition, Labview programming and research on the system of NI ELVIS (Teaching

Laboratory Virtual Instrumentation Suite).


Based on NI LabVIEW graphical system design software, NI ELVIS, with USB plug-and-play

capabilities, offers the flexibility of virtual instrumentation and allows for quick and easy

measurement acquisition and display in the field of control, telecommunication, fiber optics,

embedded design, bioinstrumentation, digital electronics, and field-programmable gate arrays

(FPGAs). Besides our teaching duties, these NI tools enable us to conduct research and software

development in different fields of sciences.

Our partners

The laboratory is maintained by National Instruments Hungary Ltd and financed by the project

HURO-0901/028/ 2.3.1. „E-Laboratory Practical Teaching for Applied Engineering Sciences”.


The NI Educational Laboratory Virtual Instrumentation Suite (NI ELVIS) features an integrated

suite of 12 of the most commonly used instruments in the lab (including the oscilloscope, digital

multimeter, function generator, variable power supply, and Bode analyser) in a compact form

factor for the lab or classroom demonstrations.

NDT (Metallographic) Lab


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The laboratory is based on NDT testing of raw materials, technological materials and structures

like welded joints. The devices in the lab follow the order of an ordinary material testing method.

There are several devices for test sample preparation (cutting, grinding, polishing and chemical

conservation). Metallographic analysis of the prepared sample is rendered possible by a

microscope. Besides, there are several NDT (metallographic) inspection equipment to create a

comprehensive analysis of the material.


Supporting the education of basic lectures like material science, technology of structural

materials, manufacturing technologies I-III. Supporting our student’s measuring for scientific

contests. With the up-to-date equipment and measuring techniques we are able to do different

testing and structural analysis of special technological materials as research and scientific

activities. Our lab is also a scientific and technical background for PhD students.


Cutting, grinding and polishing machines to create samples

Hardness testers (computer managed HB, HRC, HV)

Ultrasonic wall thickness measurement equipment

Ultrasonic hardness tester

Microscopes (Neophot with CCD & Olympus with CCD up to M=250x digital imaging)

Image analysis software

Furnace up to 1300°C (computer managed heating & cooling curve)

Qualified measuring tools (callipers, gauges, micrometers)

Pneumatics laboratory


Presentation of the most modern pneumatic systems used in industry and research in the field of

pneumatics.


Teaching of pneumatics on the basis of didactic programs of FESTO Ltd in the field of

pneumatics, electro-pneumatics, hydraulics, electro-hydraulics, PLC technique, driving

technique, mechatronics and sensor technique.

Our partners

The laboratory is sponsored by FESTO Didactic Ltd.


FESTO teaching package (PLC, VEEP emulator, wires, tools, specifications…),

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two-side pneumatic stand system: pneumatic power-supply unit, hose storage,

basic and electro-pneumatics, proportional pneumatic stock.

Robotics laboratory


Teaching of robotics and research processes concerning the robotizing of industrial processes.

Presentation of CIM systems and research of the possibilities of integration


Use and programming of recycle bin robots, carrying out of examination concerning the

operation of robots,

examination of human-machine communication on intelligent grounds, where robots and

humans are present at the same time and perhaps co-operate with each other in space.

Our partners

The laboratory is supported by KUKA Robotics Hungary Ltd, Robot-X Hungary Ltd, Flexlink

Systems Ltd.


3-axe TTT Q-robot multitasking robot, a KR5arc KUKA industrial robot, a KR5Sxx KUKA

teaching robot and a SONY SCARA SRX-611 robot connected with a delivery track

incorporated into a manufacturing cell,

8 pcs LEGO MINDSTORM robot and a sample manufacturing line consisting of 16

Fischertechnik elements developed by the university as well as a FESTO Robotino robot,

KUKA.Sim Pro software developed for programming offline KUKA robots and their

simulation.

Roller Power Test Bench and Diagnostics Lab for Passenger Cars

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The roller power test bench is appropriate for measuring and diagnosing the vehicle performance

and its condition. The installed test bench makes wild range power measurements possible in

different speed range in a safe environment.

Students can carry out a series of measurements in the laboratory about internal combustion

engine performance, exhaust gas analysis and on-board diagnostic (OBD) systems. These

measurements may support the degree theses of students.


The installed measuring equipment of Vehicle Engine Performance Measurement and Diagnostic

Laboratory have official calibration and authentication, therefore performance measurements,

exhaust gas analyses, emission measurement and diagnostic tests carried out in this laboratory are

all certified.

Our partners

Energotest Ltd


Rolling road dynamometer (TMP-350) with CAN bus based measurement data logger

unit. The equipment is suitable for performance measurement of two-wheel-drive

passenger cars and light duty vans up to 350 kW. Our lab is able provides scientific and

technical background for PhD students.

Exhaust gas analyser instrument (AVL DiGas 480) which is capable of measuring the

composition of exhaust gas. The measuring system is also equipped with Diagnostic

Trouble Codes scanner, diagnostic software and an Autodata emission database.

The laboratory is equipped with more wind generators and exhaust gas extractors.

Schneider Electric Knowledge Center


The knowledge center established by Schneider Electric Ltd offers complete solutions in the field

of energy management, electric energy distribution, control engineering and automation of

processes of industry, building automation and security, energy supply and cooling as well as

installation and the control of installation systems. The knowledge center is instrumented for the

presentation of these systems as well as for carrying out research of building supervision systems.


The laboratory is suitable for the following activities:

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Teaching of industrial controls by means of small and medium PCs and realization of real

industrial processes on twido demonstration tables built with PLCs of type M340.

Regulation of driving technical models by programming frequency changers (ATV11,

ATV31 and ATV71).

Complex engineering duties by connecting operating models into the network.

Our partners

Schneider Electric Hungary Ltd


TAC system for realizing a complete building supervision A (TAC 302, 422, 731, 100,

452, 511 OPC panel) and terrain tools,

let-in/let-out and camera system controlled by an Andover system,

the laboratory is officially informed about any development carried out by Schneider

Electric and given a sample of its products.

Water Quality Protection Laboratory


The laboratory has all basic tools applied in environmental engineering to ensure a strong

practical analytic background for field and laboratory measurements. Several research topics are

also connected to the equipment of the laboratory (such as investigation of rain water or

greywater reuse in households; thermal water final placement and the environmental effect of

thermal water utilization; surface water analysis and environmental status assessment of

watercourses surrounding Debrecen).


Environmental engineers get a good experience and knowledge on the prevention of

environmental hazards, the abolition of environmental problems, the utilization of natural

resources, cleaner technologies, analytical and monitoring methods. The lab is equipped with

modern and efficient instrumental analytical devices to get reliable and fast results for water or

sludge samples.

Our partners

TIKTVF (Green Authority), Debrecen Waterworks Ltd., Hajdú-Bihar County Municipalities

Water Works Co., Ltd. Analab Ltd., Scharlab Hungary Ltd., NNK Environmental Management,

Information Technology, Sales and Service Ltd.


Classical and instrumental analytical techniques for investigation of different water or sludge

samples:

- DIONEX ICS 3000 ion chromatographic system,

- Shimadzu Vcpn TOC instrument,

- Zetasizer Nano Z zeta potential analyser,

- WTW MultilineP4 electro-analytical set,

- BOD OXITOP IS 12 measurement, Thermostat cabinet,

- Nanocolor Linus spectrophotometer with thermoblock,

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- TURB-555 IR Turbidimeter,

- Millipore Milli-Q Integral 3 water purification unit,

- Classical analytical methods (gravimetry and titrimetry).

Welding Lab


Instruction, presentation and practice of advanced welding procedures used in industry all

over the world,

to ensure the proper technological environment for the construction of racing cars driven

by compressed air or electric motors for student’s competitions.


Introduction of the basic welding processes by welding joints of test specimens. The lab supports

the Materials Sciences and Manufacturing Engineering courses.

The laboratory is equipped with eight welding dry boxes for electric arc-welding and one for gas-

welding and metal cutting. Students learn and practise four different welding procedures:

Manual metal arc welding (MMA)

MIG-MAG gas-shielded arc welding (MIG -MAG)

Wolfram electrode welding with argon shielding gas ( GTAW -TIG, WIG )

Gas welding, flame cutting , and plasma cutting.


MILLER Powcon-300 type welding machines for MMA welding,

MILLER Synchrowave-250 type welding machines for TIG welding,

MILLER MIGBLU-300 type welding machines for gas-shielded metal-arc welding,

WELDI TIG-200i DC type welding machines for TIG and MMA welding,

WELDI AMIGO-250, WELDI MIG-320 Plus, WELDI MIG-420 type welding machines for

gas-shielded metal-arc welding.

ZF Lenksysteme Hungária Automotive Lab

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The ZF Lenksysteme Hungária Automotive Laboratory was established by ZF Lenksysteme

Hungária Ltd. in 2014. The Laboratory is suitable for performing activities like electric vehicle

construction and assembly for student competitions and for company related projects. Thanks to

its modern equipment and top class steering systems, the lab ensures the appropriate background

for related research.


The Laboratory is suitable for implementing modern engineering projects. The laboratory is

equipped with the products of ZF Lenksysteme Hungária Ltd., mountable steering systems and

steering columns. Students have the opportunity to investigate real steering systems in the lab,

which is also a scientific and technical background for PhD students.

Our partners ZF Lenksysteme Hungária Ltd


Turning lathe (OPTI TU 2807 – D280x700mm, 125-1200 f/p, 850W/400V)

Welding machine (AC/DC AWI)

Drillers, Cutters

Hand tools

Tool trolleys

Measuring instruments

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CONTACT INFORMATION

Coll. Prof. Dr. Zsolt TIBA PhD, Head of International Office

e-mail: [email protected]

Zita SZILÁGYI, international relationship coordinator of the International Office

e-mail: [email protected]

Erika THOMAS, international relationship coordinator of the International Office

e-mail: thomas.erikaveng.unideb.hu

International Office, Faculty of Engineering, University of Debrecen

H-4028, Debrecen, Ótemető utca 2-4.

mailto:[email protected]