Refrigeration and Cryogenics

Transkrypt

ROZWÓJ POTENCJAŁU I OFERTY DYDAKTYCZNEJ POLITECHNIKI WROCŁAWSKIEJ
MECHANICS AND MACHINE CONSTRUCTION
REFRIGERATION AND CRYOGENICS
II Level – MSc (3 semesters, 90 ECTS)
PROGRAM
3 SEMESTERS
Entry requirements:
MSc
Completed:
Diploma of the I level studies
in related fields.
Possible extension:
Studies of the III level (PhD)
Master Thesis,
Final Exam
Graduate:
A graduate has the detailed knowledge of
devices and installations dedicated for cooling
down to -150 C and, in the case of
cryogenics, for temperature lowering below
120 K and down to fractions of Kelvin. He or
she has the skills in the designing,
implementing and operation of both
refrigerating and cryocooling systems.
Additionally, a graduate can apply creatively
modern design methods and is well prepared
for undertaking PhD studies.
Projekt współfinansowany ze środków Unii Europejskiej w ramach
Europejskiego Funduszu Społecznego
Structure of the programme (credits)
Semester 1
Semester 2
Semester
3
1
2
BC
AC
3
4
AC
5
6
AC
FL
7
8
9
Ad R&C
10
11
12
13
14
15
16
17
Ad R&C
18
19
20
Ad R&C
21
22
23
MT
24
FE
25
26
27
28
29
30
BC
–
FL
AC
Basic Courses;
(Humanities, Foreign Language)
–
Nontechnical courses;
–
Advanced Courses;
AdR&C –
Advanced Courses in Refrigeration and Cryogenics;
MT
–
Master Thesis
FE
–
Final Exam
PLAN OF STUDIES
1st YEAR, SEMESTER 1
No.
Code
Contact hours/week
Subject/Module
L
T
lab
p
s
CHS
TSW
ECTS
Form of
Assessment
30
90
3
T
1
MSN0461 Mechanics Analytical
2
2
Modern Engineering Materials
MSN1361
(CAMD/CAMS)
1
2
45
90
1+2
T/CW
3
MSN0531
Mechatronics and Control
System
2
2
60
150
3+2
E/CW
Thermodynamic Fundamentals
of Refrigeration, Cryogenics and
Low Temperature Physics
2
45
90
2+1
T
Compressor Refrigeration
Systems
2
90
180
2+2+2
E/T/CW
Refrigerants and Coolants
1
15
30
1
T
30
60
1+1
T/CW
4
5
MSN0161
6
7
MSN0831 Heat Pumps
1
8
MSN1051 Air Condition Systems
1
9
MSN0341 Cryogenics
2
10
Cryogenic Materials and Fluids
TOTAL
1
2
2
1
1
2
3
8
1
15
15
30
1
T
75
150
2+1+2
E/T/CW
T
15
30
1
420
900
30
CHS
TSW
ECTS
Form of
Assessment
45
90
2+3
E/CW
2
45
90
1+2
T/CW
1
60
120
2+1+1
E/T/CW
2
1
1
1st YEAR, SEMESTER 2
No.
1
Code
Contact hours/week
Subject/Module
L
MSN0612 Modelling and Optimisation
MSN1040 Cooling Systems and
Refrigeration Plants
1
3
MSN0121 Absorption Refrigeration
2
4
MSN1151 Gas and Cryogenic Technologies
2
2
T
lab
p
s
2
1
1
75
150
2+2
T/CW/CW
5
Applied Superconductivity
1
15
30
1
T
6
Cryogenic Systems
1
15
30
1
T
7
Introduction to Multigeneration
Processes
1
15
30
1
T
90
180
8
CW
60
120
3
T
420
840
30
8
9
MSN1531 Individual Student Project
6
Foreign language
4
TOTAL
9
5
2
11
1
2nd YEAR, SEMESTER 3
Contact hours/week
No.
Code
Subject/Module
1
MSN1491
Integrated Production Systems
2
2
MSN 0029
Failure Analysis of Machine and
Device
2
3
MSN1561
Master Seminar
4
MSN1611
Master Thesis
L
TOTAL
L
T
lab
p
T
4
CHS
TSW
ECTS
Form of
Assessment
1
45
90
2+2
T/CW
1
45
90
2+2
T/CW
2
30
60
2
CW
600
20
CW
2
120
840
30
lab
2
p
s
S
L – Lecture T – Tutorials, l – laboratory, p – project, s – seminar,
CHS
TSW
CHS – Contact Hours (organized), TSW – Total Student Workload (h), E – Exam, T – Test, CW – Course Work
Description of the courses
1st Semester
MSN 0461
Mechanics analytical
Language: English
Course: Basic/Advanced
Level: II
Obligatory/Optional
Year (I), semester (1)
Teaching: Traditional/Distance L.
Prerequisites: Mathematical Analysis, Mechanics 2
Lecturers: Pawel Regucki, PhD; Katarzyna Strzelecka, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
30
Exam / Course work:
T
ECTS
3
Workload (h)
90
Outcome: The Knowledge of mathematical equations used in analytical mechanics.
Contents: The differential equations of motion for different systems of particles; equations of
motion in the potential field; variation rules and integral invariants; canonical transformations and
Hamilton-Jacobi equation; stability of equilibrium and stability of motion; low vibrations; circular
co-ordinate systems.
Literature:
D. Strauch, Classical Mechanics – An Introduction, Springer-Verlag Berlin Heidelberg, 2009
L. D. Landau, I. M. Lifshitz, in Theoretical Physics vol. 1 Mechanics, Elsevier Science Ltd., 2003
H. Goldstein, C. Poole, J. Safko, Classical Mechanics, 3rd edn., Addison-Wesley SanFrancisco, 2002
MSN 1361
MODERN eNGINEERING MATERIALS (CAMD/CAMS)
Language: English
Level: II
Obligatory/Optional
Prerequisites: Fundamentals of Materials Science,
Mechanics of Materials, CAD, Basics of Machine Design
Lecturer: Andrzej Chrzczonowski, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
15
30
Exam / Course work:
T
CW
ECTS
1
2
Workload (h)
30
60
Outcome: The Knowledge of materials design and selection of engineering materials using CAMD
and CAMS methods.
Contents: The basics of structure formation and engineering material properties; phase
equilibrium; phase transition; the applications of modern engineering materials; principles of
engineering material selection; software for material design (CAMD) and material selection
(CAMS).
Literature:
M.F. Ashby, Materials : engineering, science, processing and design, Elsevier Ltd, 2007
R. Tilley, Understanding Solids: The Science of Materials, John Wiley & Sons Ltd, 2004
J. Shackelford, Introduction to Materials Science for Engineers, Prentice Hall, 2009
W. Callister, Fundamentals of Materials Science and Engineering, John Wiley & Sons, 2000
MSN 0531
MECHATRONICS AND CONTROL SYSTEMS
Language: English
Level: II
Obligatory/Optional
Prerequisites: Mathematical Analysis, Physics, Basics of Automatics
Lecturers: Artur Jedrusyna, PhD; Krzysztof Tomczuk, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
30
30
Exam / Course work:
E
CW
ECTS
3
2
Workload (h)
90
60
Outcome: A brief introduction into the design and programming of modern embedded systems.
The presentation of internal construction, principles of operation, typical functions, applications
and programming techniques of the Simatic programmable logic cotrollers (PLC).
Contents: The presentation of modern industrial control systems (including Freelance 2000, PS7,
Profinet); the construction, principles of operation and programming methods for Simatic PLCs;
advanced options (extension blocks, including communication modules) of Simatic PLC; the
applications of advanced functions (high speed counters and PWM generators); the fundamentals
of microprocessor systems; internal architecture of the exemplary 8-bit microcontroller; methods
for program development and troubleshooting (assembly language and C language); remarks on
microcontroller interfacing with I/O devices, selected applications of embedded systems.
Literature:
C. Sabri, Mechatronics, John Wiley & Sons, 2007
D.G. Alciatore, M.B. Histand, Introduction to mechatronics and measurement systems, McGrawHill, 2007
A. Smaili, F. Mrad, Applied mechatronics , Oxford University Press, 2008
S7-200 System user’s manuals, Siemens Automation Systems
http://www.automation.siemens.com/simatic/portal/html_76/techdok_simatic/microsyst_techdoku.ht
m
THERMODYNAMIC FUNDAMENTALS OF REFRIGERATION, CRYOGENICS
AND LOW TEMPERATURE PHYSICS
Language: English
Level: II
Obligatory/Optional
Prerequisites: Technical Thermodynamics, Physics
Lecturers: Maciej Chorowski, Prof.; Jaroslaw, Fydrych, PhD; Jaroslaw Polinski, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
30
15
CW
Exam / Course work:
T
1
ECTS
2
Workload (h)
30
60
Outcome: The Knowledge of thermodynamic and physical fundamentals of refrigeration,
cryogenics and low temperature physics including superconductivity, thermal stabilization and
heat transfer.
Contents: Thermodynamic principles of refrigeration and cryogenic processes (phenomenological
and statistical approach); implications of Nernst theorem in quest towards absolute zero;
introduction to low-temperature thermodynamic system optimizations based on the minimization
of entropy generation; basic processes used in refrigeration and cryogenics; introduction to
superconductor thermodynamics and thermal stabilization.
Literature:
Ch. Kittel, H. Kroemer, Thermal Physics, W.H. Frejman and Company, 1980
A.M. Arkharow, I.V. Marfenina, Ye.I. Mikulin, Cryogenic systems, Bauman Moscow State
University Press, Moscow, 2000
M. Chorowski, Kriogenika – podstawy i zastosowania, IPPU MASTA, Gdańsk, 2007 (Cryogenics –
Fundamentals and applications, in Polish)
MSN 0161
Compressor Refrigeration Systems
Language: English
Level: II
Obligatory/Optional
Prerequisites: Technical Thermodynamics, Fluid Mechanics
Lecturers: Stefan Reszewski, PhD; Marek Zak, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
30
30
30
Exam / Course work:
E
T
CW
ECTS
2
2
2
Workload (h)
60
60
60
Outcome: The Knowledge of thermodynamic cycles and constructions of compressor-based
refrigeration plants, cycles analysis and calculations, installation components selection, laying
refrigeration pipes, simulation and comparison of refrigeration thermodynamic cycles for
dedicated applications.
Contents: Simplifying assumptions made in modeling procedures; construction of physical model
of system under study; dimensional space; Buckingham theorem; dimensional physical process;
similarity invariants; model similarity; dimensionless mathematical model; least squares method;
identification of model parameters; model verification; optimization of multidimensional models;
nonlinear constraint optimization methods; application of numerical methods in modeling and
optimization procedures.
Literature:
Handbook: refrigeration, ASHRAE, 2006
W.F. Stoecker, Industrial refrigeration handbook, McGraw-Hill, 1998
R. Miller, M.R. Miller, Air conditioning and refrigeration, McGraw-Hill Professional Publishing,
2006
R. Ciconkov, Refrigeration - Solved examples, Amer Society of Heating, 1996
MSN 0181
REFRIGERANTS AND COOLANTS
Language: English
Level: II
Obligatory/Optional
Lecturer: Boguslaw Bialko, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
15
Exam / Course work:
T
ECTS
1
Workload (h)
30
Outcome: The knowledge concerning the properties of refrigerants and coolants.
Contents: Symbols and international codes of Freon’s and natural fluids (ammonia, propane,
isobutane, n-butane, carbon dioxide); international regulations (Montreal’s Protocol); physical,
chemical, thermodynamic properties and ecological indicators (ODP, HGWP, GWP, TEWI) of
refrigerants, brine and glycol; zoetrope and azeotropic mixtures.
Literature:
H. Styles, Technical Certification for Refrigerants, Amer Technical Pub, 2009
D. Wirz, Commercial Refrigeration for Air Conditioning Technicians, Delmar Cengage Learning,
2005
D.T. Solutions, Refrigerant Transition & Recovery Certification Program Manual for Technicians,
Delmar Cengage Learning, 2001
B. Whitman, B. Johnson, J. Tomczyk, E. Silberstein, Refrigeration and Air Conditioning Technology,
Delmar Cengage Learning, 1999
J. Tomczyk, Alternative Refrigerant Blends & Oils, Esco Pr, 2003
MSN 0831
Heat PUMPS
Language: English
Level: II
Prerequisites: Technical Thermodynamics, Heat Transfer
Lecturer: Stefan Reszewski, PhD
Lecture
Tutorials
Laboratory
Hours / sem. (h)
15
Exam / Course work:
T
ECTS
1
Workload (h)
30
Obligatory/Optional
Project
15
CW
1
30
Seminar
Outcome: The Knowledge of heat pumps theory and low-temperature heat sources utilization.
Acquired knowledge will allow leading the thermodynamic and energetic analyses of heat pumps
systems, enabling utilization of optimum solutions for local environmental conditions.
Contents: Theoretical basics; heat pump’s rules of working in different type of heating and airconditioning systems; calculation and design procedure of heat pump devices and complex
systems; characterization, technical and useful parameters of bottom heat sources for heat pumps;
bases of selection and estimation of bottom heat sources usefulness; economic analysis of heat
pumps application in heating engineering, air-conditioning techniques and in industry; examples
and analysis of system’s technical solutions based on high-performance heat pumps.
Literature:
B.C. Langley, Heat Pump Technology, Prentice Hall, 2001
E. Silberstein, Heat Pumps, Delmar Cengage Learning, 2002
R. Radermacher, Y. Hwang, Vapor Compression Heat Pumps with Refrigerant Mixtures, CRC
Press, 2005
R. Jazwin, Troubleshooting & Serving Heat Pumps, Esco Pr, 2002
MSN 1051
AIR CONDITION SYSTEMS
Language: English
Level:
II
Obligatory/Optional
Lecturer: Boguslaw Bialko, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
15
Exam / Course work:
T
ECTS
1
Workload (h)
30
Outcome: The knowledge about air-condition technologies, practical methods of different room
heat balances and the selection of installation components.
Contents: Review of air-condition technologies; room air rotation, heat and pollutions elimination
(air filtration); i-x diagram for air (dew-point, fog); fans (types, constructions, application); heat
recovery; devices and apparatus in air-condition (compact, split, multi-split air conditioners).
Literature:
W.P. Jones, Air Conditioning Engineering, Butterworth-Heinemann, 2000
W.P. Jones, Air Conditioning Application and Design, Butterworth-Heinemann, 1996
S. Wang, Handbook of Air Conditioning and Refrigeration, McGraw-Hill Professional, 2000
F.C. McQuiston, J.D. Parker, J.D. Spitler, Heating, Ventilating and Air Conditioning Analysis and
Design, John Wiley & Sons, 2000
MSN 0341
CRYOGENICS
Language: English
Level: II
Obligatory/Optional
Prerequisites: Technical Thermodynamics, Heat Transfer,
Fundamentals of Materials Science
Lecturers: Maciej Chorowski, Prof.; Jaroslaw, Fydrych, PhD;
Jaroslaw Polinski, PhD; Agnieszka Piotrowska-Hajnus, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
30
15
30
Exam / Course work:
E
T
CW
ECTS
2
1
2
Workload (h)
60
30
60
Outcome: The Knowledge of theoretical fundamentals of cryogenics, constructions of gas
cryocoolers, the thermodynamic cycles used in design of cryogenic refrigerators and liquefiers,
practical examples of the cycle applications. Skills in handling with liquid gases. Experience in
experimental methods used in cryogenic temperature.
Contents: Definitions and historical background of the cryogenics; theoretical fundamentals and
processes in cryogenics; introduction to cycles: simple and complex throttle expansion cycles, gas
expander cycles, combined cycles (Heylnadt and Claude cycles); modeling and optimization of
cryogenic cycles; introduction to the construction of cryocooler; gas cryocolers (Stirling, GiffordMcMahon, pulse tube); dilution and adiabatic demagnetization cryocoolers; introduction to low
temperature thermometry.
Literature:
J.G. Weisend II, Handbook of Cryogenic Engineering, Taylor&Francis, USA 1998
A.R. Jha, Superconductor Technology, John Wiley & Sons, Inc., 1998
M. Chorowski, Kriogenika – podstawy i zastosowania, IPPU MASTA, Gdańsk, 2007 (in Polish)
CRYOGENIC MATERIALS AND FLUIDS
Language: English
Level: II
Obligatory/Optional
Prerequisites: Technical Thermodynamics, Heat Transfer,
Lecturer: Jaroslaw Fydrych, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
15
Exam / Course work:
T
ECTS
1
Workload (h)
30
Outcome: Knowledge of the properties of materials applied in cryogenic engineering including
construction materials, thermal and electrical insulators, Basic knowledge of physical, chemical and
thermodynamic properties of cryogenic materials and fluids. Safety in handling with cryogenic
liquids.
Contents: The influence of low temperature upon different materials; overview of the construction
materials and insulations used in cryogenic engineering; properties of cryogenic liquids; safety
rules in cryogenics, oxygen deficit hazard.
Literature:
G. Ventura, L. Risegari, The Art of Cryogenics, Low-Temperature Experimental Techniques,
Elsevier, 2008
J.G. Weisend II, Handbook of Cryogenic Engineering, Taylor&Francis, USA 1998
K.D. Williamson Jr, F.J. Edeskudy, Liquid Cryogens, Volume I: Theory and Equipment, CRC Press
Inc., USA 1983
F. Pobell, Matter and Methods at Low Temperature, Sprigner, Second Edition, USA1996
F.J. Edeskuty, W.F. Stewart, Safety in the handling of cryogenic fluids, Plenum Press,
New York, 1996
2nd Semester
MSN 0612
MODELLING AND OPTIMIZATION
Language: English
Level: II
Obligatory/Optional
Prerequisites: Linear Algebra, Calculus (functions of multiple
variables, multiple integrals)
Lecturer: Aleksander Sulkowski, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
15
30
Exam / Course work:
E
CW
ECTS
2
3
Workload (h)
30
60
Outcome: The students will possess knowledge concerning application of numerical methods for
physical processes and mechanical systems modeling.
Contents: Simplifying assumptions made in modeling procedures; construction of physical model
of system under study; dimensional space; Buckingham theorem; dimensional physical process;
similarity invariants; model similarity; dimensionless mathematical model; least squares method;
identification of model parameters; model verification; optimization of multidimensional models;
nonlinear constraint optimization methods; application of numerical methods in modeling and
optimization procedures.
Literature:
E.K.P. Chong, S.H. Żak, An Introduction to Optimization, J.Wiley &Sons Inc., New York 1996
W. Kasprzak, B. Lysik, M. Rybaczuk, Measurements, Dimensions, Invariant Models and Fractals,
SPOLOM, Wroclaw-Lviv, 2004
M.S. Bazaraa, H.D. Sherali, C.M. Shetti, Nonlinear Programming: Theory and Algorithms, J.Wiley
& Sons Inc., New York 1993
S.C. Fang, S. Puthenpura, Linear Optimization and Extensions: Theory and Algorithms, Englewood
Cliffs, NJ: Prentice Hall, 1993
MSN 1041
COOLING SYSTEMS AND REFRIGERATION PLANTS
Language: English
Level: II
Obligatory/Optional
Lecturer: Marek Zak, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
15
30
Exam / Course work:
T
CW
ECTS
1
2
Workload (h)
30
60
Outcome: The Knowledge of regulations and standards used in designing and operating of cooling
systems and refrigeration plants. The ability to design cooling and refrigerating systems.
Contents: The safety rules – the influence on cooling systems choice; the classification of rooms,
direct and indirect systems; pressure, gravitational and pump systems in direct systems;
multistage and cascade systems including economizer; the design rules of refrigeration and
coolant plants and installation of oil circulation, air vent, safety and emergency ventilation.
Literature:
Handbook. Refrigeration, ASHRAE, Atlanta, 2006
W.F. Stoecker, Industrial refrigeration handbook, New York, McGraw-Hill, 1998
İ. Dinçer, Refrigeration systems and applications, Chichester, John Wiley & Sons, 2003
S.K. Wang, Handbook of air conditioning and refrigeration, New York, McGraw-Hill, 2001
EN 378:2008 Refrigerating systems and heat pumps – Safety and environmental requirements
EN 1861:1998 Refrigerating systems and heat pumps – System flow diagrams and piping and
instrument diagrams - Layout and symbols
EN 13136:2001 Refrigerating systems and heat pumps – Pressure relief devices and their associated
piping – Method for calculation
Catalogues of refrigeration components and units
Computer programs intended for refrigeration.
MSN 0121
ABSORPTION REFRIGERATION
Language: English
Level: II
Obligatory/Optional
Prerequisites: Technical Thermodynamics, Fluid Mechanics,
Compressor Refrigeration Systems;
Refrigerants and Coolants
Lecturers: Stefan Reszewski, PhD; Bartosz Zajaczkowski, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
30
15
15
Exam / Course work:
E
T
CW
ECTS
2
1
1
Workload (h)
60
30
30
Outcome: The knowledge and skills in cycle modelling and heat exchangers design for absorption
regeneration.
Contents: Basic design of industrial absorption devices for the solution NH3+H2O and H2O+LiBr;
the methodology of the absorption cycle design on the h-ξ diagram; typical apparatus
constructions and formulas for the thermal calculations; the guidelines for the apparatus design.
Literature:
Handbook: refrigeration, ASHRAE 2006
W.F. Stoecker, Industrial refrigeration handbook, McGraw-Hill, 1998
K.E. Herold, R. Rademacher, S.A. Klein, Absorption Chillers and Heat Pumps, CRC Press LLC,
1996
G. Alefeld, R. Rademacher, Heat Conversion Systems, CRC Press, 1994
Web Site: „3D Absorption ” http://fluid.itcmp.pwr.wroc.pl/~kasper/absorpcja3d/
International Journal of Refrigeration
MSN 1151
GAS AND CRYOGENIC TECHNOLOGIES
Language: English
Level: II
Obligatory/Optional
Prerequisites: Cryogenics, Technical Thermodynamics, CAD,
Basics of Machine Design
Lecturers: Jaroslaw Fydrych, PhD; Jaroslaw Polinski, PhD; Agnieszka Piotrowska-Hajnus, PhD; Wojciech
Gizicki, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
30
30
Exam / Course work:
T
CW
ECTS
2
2
Workload (h)
60
60
Outcome: Knowledge of the application of cryogenic technologies in technical gas production,
metallurgy, medicine and food production, as well as distribution and storage of cryogenic liquids
and fuels (LNG, liquid hydrogen). Skills in the designing of cryostats and simple cryogenic
equipments. The knowledge of novel cryogenic technologies used or planned to use in power
engineering industry.
Contents: Cryogenic technologies applied for the production of gases, frozen food industry and
medical applications. Introduction to vacuum engineering used in cryogenics, cryopumping;
Design of cryostat and cryogenic transfer lines; Cryogenic recycling of polymers. Low-temperature
technologies in metal treatment. Cryogenic technologies in power engineering, including
renewable energy generation and CO2 emission reduction. Gas separations aimed to oxy-fuel and
CO2 sequestration. LNG production and regasification. Hydrogen production, storage and
distribution; the influence of the technologies on thermodynamic efficiency of the power
generation cycles.
Literature:
A.R. Jha, Cryogenic Technology and Applications, Elsevier, USA, 2008
R.C. Scurlock, Low-Loss Storage and Handling of Cryogenic Liquids: The Application of Cryogenic
Fluid Dynamics, Kryos Publications, United Kingdom, 2006
J.G. Weisend II, Handbook of Cryogenic Engineering, Taylor&Francis, USA, 1998
APPLIED SUPERCONDUCTIVITY
Language: English
Level: II
Obligatory/Optional
Prerequisites: Thermodynamic Fundamentals of Low Temperature
Physics and Cryogenics
Lecturers: Maciej Chorowski, Prof; Jaroslaw Polinski, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
15
Exam / Course work:
T
ECTS
1
Workload (h)
30
Outcome: The knowledge of theoretical fundamentals of superconductivity, superconductors’
calcification, production, cryogenic stabilization and their applications.
Contents: Superconductivity; classification, fundamental properties and production of
superconductors; superconducting magnetic coils; applications of superconducting magnets;
superconductors for power transmission (cables, transformers, and current-limiting devices),
superconducting resonators, filters and detectors; superconductors in microelectronics;
superconductor cryogenic stabilization.
Literature:
W. Buckel, R. Kleiner, Superconductivity: Fundamentals and Applications, Wiley-VCH, 2004
P. J. Lee, Engineering Superconductivity, Wiley-IEEE Press; 1 edition, 2001
C.P. Poole., H.A. Farach, R.J. Creswick, R. Prozorov, Superconductivity, Academic Press, 2007
V.L. Ginzburg, E.A. Andryushin, Superconductivity, World Scientific Publishing Company, 2004
CRYOGENIC SYSTEMS
Language: English
Level: II
Prerequisites: Cryogenics
Lecturer: Maciej Chorowski, Prof; Jaroslaw Fydrych, PhD
Lecture
Tutorials
Laboratory
Hours / sem. (h)
15
Exam / Course work:
T
ECTS
1
Workload (h)
30
Outcome: Knowledge of cryogenic refrigeration and liquefaction
industrial and medical facilities.
Obligatory/Optional
Project
Seminar
systems applied in research,
Contents: Introduction to cryogenic systems as groups of cryogenic units and nodes. Descriptions
of cryogenic refrigeration and liquefaction systems dedicated for cooling and thermostatting at
low temperatures in large, medium and small research, industrial and medical facilities, like
superconducting accelerators, fusion reactors, neutral beam injectors, infrared detectors, hightemperature superconducting cable, magnetic resonance imaging devices. Cryogenic gas
separation and liquefaction plants.
Literature:
Ventura G., Risegari L., The Art of Cryogenics, Low-Temperature Experimental Techniques,
Elsevier, 2008
INTRODUCTION TO MULTIGENERATION PROCESSES
Language: English
Level: II
Obligatory/Optional
Prerequisites: Cryogenics
Lecturer: Maciej Chorowski, Prof; Wojciech Gizicki, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
15
Exam / Course work:
T
ECTS
1
Workload (h)
30
Outcome: The theoretical knowledge of multigeneration processes (cogeneration and trigeneration
systems) and power plant design, operation, and maintenance.
Contents: The introduction to power plant design, operation, and maintenance; cycle optimization
and reliability, technical details on sizing, plant layout, fuel selection, types of drives, and the
performance characteristics of all major components in a cogeneration or combined cycle power
plant; comparison of various energy systems; latest cycles and power augmentation techniques;
detailed analysis of available equipment; advantages and disadvantages of fuels.
Literature:
M.P. Boyce, Handbook for cogeneration and combined cycle power plants, American Society of
Mechanical Engineers, 2001
B.F. Kolanowski, Small-scale cogeneration handbook, Fairmont Press, 2003
MSN 1531
INDIVIDUAL STUDENT PROJECT
Language: English
Prerequisites:
Lecturer:
Level: II
Obligatory/Optional
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
90
Exam / Course work:
CW
ECTS
8
Workload (h)
180
Outcome: The student will possess the technical skills and experience concerning engineering
design of the installation, apparatus or devices.
Contents: depends on subject area.
Literature: depends on subject area.
3rd Semester
MSN 1491
INTEGRATED PRODUCTION SYSTEMS
Language: English
Level: II
Obligatory/Optional
Prerequisites: Production Technologies, Mechanics of Materials,
Fundamentals of Materials Science, CAD
Lecturer: Janusz Skrzypacz, PhD
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
30
15
Exam / Course work:
T
CW
ECTS
2
2
Workload (h)
60
30
Outcome: The knowledge of the methods of efficiency advance of the production systems by the
operations integration and using informatics instruments; The knowledge about the function of
commercial CAx systems in modern company. Skills of usage adequate software for an every level
of manufacturing process.
Contents: The basis of manufacturing technology; the structure of the production system;
integration of the operations for production preparations; integration and aggregation basics of
commercial CAD/CAM systems; STEP format, Rapid Prototyping; Rapid Tooling, Reverse
Engineering; PLM and PDM systems, integration of the production technologies for one- and
several-machine systems; operations integration in logistics and informatics. Some aspects of CAx
system implementation in a company.
Literature:
W. Compton, Design and analysis of integrated manufacturing systems, National Academy Press,
Washington D.C., 1988
M.P. Groover, Automation, Production Systems, and Computer-Integrated Manufacturing,
C.T. Leondes, Computer aided and integrated manufacturing systems
Volume 1: Computer Techniques
Volume 2: Intelligent Systems Technologies
Volume 3: Optimization Methods
Volume 4: Computer Aided Design / Computer Aided Manufacturing (CAD/CAM)
Volume 5: Manufacturing Processes
F. Fuchs, H. Meyer, K. Thiel, Manufacturing Execution Systems: Optimal Design, Planning, The
McGraw-Hill Companies Inc., 2009
G. Chryssolouris, D. Mourtzis, Manufacturing, Modelling, Management And Control, Elsevier Ltd.
T-Ch. Chang, R.A. Wysk, H-P. Wang, Computer-Aided Manufacturing, Elsevier Ltd.
D.J W. Chapman, Manufacturing systems — An introduction to the technology, Elsevier Ltd.
MSN 0029
FAILURE ANALYSIS OF MACHINES AND DEVICES
Language: English
Level: II
Obligatory/Optional
Prerequisites: Strength of Materials, Basics of Machine Design,
Lecturer: Maciej Chorowski, Prof.; Marek Gawlinski, Prof.
Lecture
Tutorials
Laboratory
Project
Seminar
Hours / sem. (h)
30
15
Exam / Course work:
T
CW
ECTS
2
2
Workload (h)
60
30
Outcome: Student should be able to carry-out an failure analysis of both design and exploitation
stage to improve design and to give prevention directives.
Contents: The fundamentals of failure analysis and prevention methods; the types of failures and
their potential consequences; algorithms of failure analysis basing on exploitation examples.
Literature:
G.E. Dieter, Engineering Design: A Materials and Processing Approach, McGrawHill, New York
2000
K.G. Budzinski, M.K. Budzinski, Engineering Materials: Properties and Selection, Prentice Hall,
Upper Saddle River, New Jersey, 2005
H.E. Boyer, Metal Handbook No: 10, Failure Analysis and Prevention, American Society for metals,
Ohio, 1975,
MSN 1561
MASTER SEMINAR
Language: English
Level: II
Prerequisites:
Lecturer: Maciej Chorowski, Prof; Marek Gawlinski, Prof.
Lecture
Tutorials
Laboratory
Hours / sem. (h)
Exam / Course work:
ECTS
Workload (h)
Outcome: Presentation of the master thesis progress.
Obligatory/Optional
Project
Seminar
30
CW
2
60
MSN 1611
MASTER THESIS
Language: English
Prerequisites:
Lecturer:
Obligatory/Optional
Level: II
Lecture
Hours / sem. (h)
Exam / Course work:
ECTS
Workload (h)
Outcome: Master thesis.
Tutorials
Laboratory
Project
CW
20
600
Seminar

Refrigeration and Cryogenics

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