master programme «computer technologies for...
TRANSCRIPT
POWER ENGINEERING INSTITUTE
Leonid Belyaev Viktor Bespalov
Alexander Matveev Department Nuclear and Thermal Power Plants
Tomsk Polytechnic University
MASTER PROGRAMME «Computer Technologies
for Design of Thermal and Nuclear Power Plants»
POWER ENGINEERING INSTITUTE
Master Programmes
Major «Heat and Power Engineering» § Heat and Mass Transfer Processes and Installations
§ Thermal Physics in Heat and Power Engineering
§ Water and Fuel Power Engineering
§ Heat and Electric Power Generation Technology
§ Computer Technologies for Design of Thermal and Nuclear Power Plants
POWER ENGINEERING INSTITUTE
Computer Technologies for Design of Thermal and Nuclear Power Plants
PROGRAMME CONCEPT
ü The programme prepares its graduates for development of new equipment for Thermal and Nuclear Power Plants (TPP and NPP)
ü It focuses on advanced studies in natural and engineering sciences, computer and informaIon technologies
ü The graduates gain experience in usage of modern soJ-‐ and hardware tools for design equipment of power energe;c and for opera;on of TPP and NPP
ü The graduates are prepared for research, simula;on of strength proper;es and technological processes of heat transfer, development and implementa;on of new technologies of conver;ng the natural energy into electricity
POWER ENGINEERING INSTITUTE
PROGRAMME OBJECTIVES
The programme prepares graduates for:
ü Research and problem solving in development and op;miza;on of techniques and equipment for TPP and NPP using computer-‐aided technologies
ü Engineering design of TPP and NPP machinery and equipment taking into account the requirements and standards of process engineering, environment protec;on and safety regula;ons
ü Independent life-‐long learning and professional development
Computer Technologies for Design of Thermal and Nuclear Power Plants
POWER ENGINEERING INSTITUTE
Code Programme Learning Outcomes
Professional Learning Outcomes R1 use in-‐depth knowledge of natural sciences, mathemaIcs and
engineering in TPP and NPP design
R2 idenIfy and solve problems of engineering analysis related to TPP and NPP equipment and machinery development using the system analysis
R3 apply computer and informaIon technologies in design of TPP and NPP and development of thermal and mechanical equipment
R4 conduct theoreIcal and experimental research of thermodynamic, heat and mass transfer processes in thermal and power equipment, interpret, present and give pracIcal recommendaIons for results implementaIon
R5 develop mathemaIcal models of engineering processes, calculate strength properIes of complex systems using modern tools and design databases for TPP and NPP
POWER ENGINEERING INSTITUTE
Code Programme Learning Outcomes
Personal Learning Outcomes R6 use scienIfic knowledge and creaIvity, analyze, synthesize and criIcally
evaluate data
R7 demonstrate knowledge of foreign language at the level allowing to communicate effecIvely with the internaIonal engineering community, work out documentaIon, present and defend outcomes of innovaIve engineering acIvity
R8 funcIon effecIvely as an individual and as a member and leader of a team that may be composed of different disciplines and levels, take responsibility for the results and follow the corporate culture of organizaIon
R9 demonstrate in-‐depth knowledge of social, ethical, cultural and sustainable development issues of innovaIve engineering acIvity
R10 engage in independent learning and conInuous professional development
POWER ENGINEERING INSTITUTE
Module Credits R1 R2 R3 R4 R5 R6 R7 R8 R9 R10
General cycle
Philosophical and methodological problems of science and technology
3 1 1 1
Professional Foreign Language 4 3 1
Economy and ProducIon Control 2 1 1
MathemaIcal Modeling 2 1 1
Data-‐driven design 3 1 2
ALLOCATION OF LEARNING OUTCOMES
POWER ENGINEERING INSTITUTE
Module Credits R1 R2 R3 R4 R5 R6 R7 R8 R9 R10
PROFESSIONAL CYCLE
Modern Challenges of Thermal Power Engineering and Thermal Technologies
3 1 1 1
Problems of energy and resource saving in heat power engineering, heat engineering and heat technology
3 2 1
Ecological Safety 3 2 1 Principles of effecIve process management in heat power engineering, heat engineering and heat technology
3 1 2
Computer design of industry’s equipment 6 4 1 1
The Use of Computer Systems in Solving Applied Problems 4 1 2 1
POWER ENGINEERING INSTITUTE
Module Credits R1 R2 R3 R4 R5 R6 R7 R8 R9 R10
PROFESSIONAL CYCLE
SimulaIon of complex systems 4 2 1 1 TPP and NPP Heat Exchangers and Compressors 4 1 2 1
Technological systems and of TPP and NPP 4 2 1 1
Reliability and OperaIon Modes of TPP 4 2 2
Design of Thermal Power Units and Subsystems 4 1 2 1
Technology of TPP and NPP Design OrganizaIon 3 2 1
Research Project 16 1 2 2 5 2 1 1 1 1 Design PracIce 4 2 1 1 Research PracIce 17 2 2 2 5 1 1 1 1 2 Master’s Thesis 24 1 5 3 3 3 3 1 3 2
POWER ENGINEERING INSTITUTE
Details
Learning outcomes: M1 (R1): Knowledge and understanding of HPP and NPP typical layouts of steam turbine and gas turbine plants design methods M2 (R3): Experience in using the current technical regulations, standards, requirements and rules in design activity M3 (R1): Knowledge of design developing organization structure, procedure for issuing assignments to related specialists, list of assignment issuance, schedule of assignment issuing M4 (R8): ability to work in teams solving issues related to creation of new and/or reconstruction of the existing energy facilities
Compliance of module learning outcomes to the Programme learning outcomes
Design Practice
Programme LO R1 R2 R3 R4 R5 R6 R7 R8 R9 R10 Credits 2 1 1
Module LO М1, М3 М2 M4
POWER ENGINEERING INSTITUTE
Details
Learning outcomes: M1 (R1): Knowledge of patent and literature references for investigated theme M2 (R1): Knowledge of requirements to the research and technical documentation preparation Знание правил и технических требований, учитывающих особенности конструирования и изготовления оборудования ТЭС и АЭС, проектирования, сооружения, монтажа и эксплуатации электростанций M3 (R4): ability to analyze and process experimental data of heat and mass transfer, thermophysical and thermal-hydraulic testing of Thermal and Nuclear Power Plants equipment; M4 (R3): ability to apply software products and information technologies related to heat power engineering, in investigations of Thermal and Nuclear Power Plants equipment; M5 (R4): ability to interpret the data and draw the conclusions;
Research Practice
POWER ENGINEERING INSTITUTE
Details
Learning outcomes: M6 (R4): ability to compare the results of Thermal and Nuclear Power Plants equipment research with national and foreign analogues; M7 (R4): experience in use of modern software packages in conducting research; M8 (R7): use of foreign literature in conducting research; M9 (R10): experience of independent work in solving heat and mass transfer, thermophysical and thermal-hydraulic problem in thermal power engineering; M10 (R3) experience in use of current technical standards, norms and regulations; M11 (R2): ability to analyze the cost efficiency of Thermal and Nuclear Power Plants equipment design; M12 (R4): experience in making full descriptions of the research, presenting the results of the work in the form of reports, abstracts, articles accomplished in accordance with the requirements;
Research Practice
POWER ENGINEERING INSTITUTE
Details
Learning outcomes: M13 (R8): ability to work as a member and/or leader and to be responsible for outcomes M14 (R9): knowledge and understanding of social, ethic and cultural issues of innovative engineering, competence in sustainable development issues М15 (R10): ability to acquire new knowledge and engage into independent life-long learning
Programme LO R1 R2 R3 R4 R5 R6 R7 R8 R9 R10
Credits 2 3 3 3 2 -‐ -‐ 1 1 1
Module LO М1, М2 М11
М4, М10
М3, M5, M6, M7, M12
М4, М7 -‐ -‐
М5, М7
М6, М7 М6
Compliance of module learning outcomes to the Program learning outcomes
Research Practice
POWER ENGINEERING INSTITUTE
Topics of the thesis in engineering design include modernization, reverse engineering, enhancement of safety standards in analogues, prototypes of the Russian and foreign TPP and NPP power units as well as innovative projects.
Main part of the thesis is performed in the following sequence: analysis of innovations, design problem setting, search for innovative options, engineering calculations, equipment layout, process design, organizational design, ergonomic design, technical and economic evaluation of engineering solutions, prediction of the effect from the implementation of a given solution, project evaluation and analysis.
Details
Master Thesis
POWER ENGINEERING INSTITUTE
Details Master Thesis
Learning Outcomes: M1 (R6): ability to analyze the current state of nuclear power engineering and traditional thermal power engineering and set independently engineering tasks of Thermal and Nuclear Power Plants design; M2 (R2): ability to solve engineering tasks, to integrate knowledge from different fields of study, to make decisions in complex engineering tasks involving high degree of uncertainty and lack of information basing on the acquired knowledge and criteria; M3 (R3): experience in use of applied software and information resources used to get new information Thermal and Nuclear Power Plants design; M4 (R5): experience in modeling and design of Power Engineering processes and objects, professional presenting and preparing of the design project and documentation;
POWER ENGINEERING INSTITUTE
Details Master Thesis
Learning Outcomes: M5 (R9): understanding of social, ecological, economic impact of issues related Thermal and Nuclear Power Plants design, maintenance and accident forecasting; M6 (R6): оценка эффективности систем безопасности и радиационной обстановки инженерно-технических мероприятий гражданской обороны и предупреждения чрезвычайных ситуаций M7 (R5): ability to use the Thermal and Nuclear Power Plants equipment modeling methods; M8 (R3): ability to evaluate the results of Thermal and Nuclear Power Plants design; M9 (R10): experience of independent work in solving heat and mass transfer, thermophysical and thermal-hydraulic problem in thermal power engineering; M10 (R4): ability to choose appropriate research methods, conduct experiments, interpret the data and draw conclusions;
POWER ENGINEERING INSTITUTE
Details Master Thesis
Learning Outcomes: M11 (R5): ability to design mathematical models of Thermal and Nuclear Power Plants equipment M12 (R3): experience of mathematical (computer-aided) modeling and object optimizing of Thermal and Nuclear Power Plants equipment, including standard and specific software packages M13 (R6): the experience of evaluation of project cost efficiency М14 (R3): experience in use of current technical standards, norms and regulations; M15 (R3): experience in Thermal and Nuclear Power Plants equipment maintenance; М16 (R4): ability to use standard and specific software packages in conducting analytic and experimental investigations М17 (R7): use of foreign literature in conducting research
POWER ENGINEERING INSTITUTE
Details Master Thesis
Learning Outcomes: M18 (R7): to communicate effectively; knowledge of professional terminology, skills of presenting information and making presentations as well as experience in presenting and defending independently performed projects M19 (R8): ability to work individually and as a member and/or leader and to be responsible for outcomes M20 (R4): ability to interpret the data and analyze them and make the conclusions based on the of literature available; M21 (R10): ability to acquire new knowledge and engage into independent life-long learning M22 (R9): knowledge and understanding of social, ethic and cultural issues of innovative engineering practice; М23 (R9): competence in sustainable development issues M24 (R7): experience in independent evaluation and defense of project’s results; making the presentations
POWER ENGINEERING INSTITUTE
Details Master Thesis
Programme LO R1 R2 R3 R4 R5 R6 R7 R8 R9 R10
Credits 1 4 -‐ 4 2 4 1 2
Module LO М2 М3, M8, M12, M14,
M15,
M10,M16,M20
М4, M7, M11
М1, M6, M13
М17,M18,M24
М19 М5, M22,M23
M9, M21
Compliance of the Module Learning Outcomes with the Program Learning Outcomes
POWER ENGINEERING INSTITUTE
Assessment of Learning Outcomes
Module Learning Outcomes
On-going assessment: accomplishment of tasks, projects, labs, etc).
Final assessment: exam, credit test
Programme Learning Outcomes:
• Projects / Practice / Research Work Reports
• Master Thesis (Attestation Commission includes about 60 % of industry
representatives)
Industry is involved in development and improvement of LO
POWER ENGINEERING INSTITUTE
a) Forms
lectures, practical classes, labs, projects, seminars,
practices, independent student work, workshops with
representatives of Russian and foreign companies.
b) Methods
IT-tools, teamwork, case-study, group discussions,
prelimenrary independent work, feedback
Teaching methods
Computer Technologies for Design of Thermal and Nuclear Power Plants
POWER ENGINEERING INSTITUTE
Computer Technologies for Design of Thermal and Nuclear Power Plants
NX Academic Bundle (UGACAD200)
X 8 Redefines Productivity
Siemens PLM SoGware’s driving mission is to work collabora;vely with companies to deliver open solu;ons that help them turn more ideas into successful products. These open solu;ons enable companies to transform their process of innova;on and maximize the value derived from their products throughout their en;re lifecycle.
Purchased Software
Modules: «Computer design of industry’s equipment» «Design of Thermal Power Units and Subsystems»
POWER ENGINEERING INSTITUTE
Рurchased books
Computer Technologies for Design of Thermal and Nuclear Power Plants
1. Rolf Kehlhofer, Bert Rukes, Frank Hannemann, Franz Stirnimann. Combined-Cycle Gas & Steam Turbine Power Plants, 3rd Edition. Publication Date: March 20, 2009. ISBN-10: 1593701683. ISBN-13: 978-1593701680. Edition: 3. P. 430. (≅75$)
2. Kam W. Li. Power Plant System Design. Publication Date: February 22, 1985. ISBN-10: 0471888478. ISBN-13: 978-0471888475. Edition: 1. P. 656. (≅145$)
3. Ronald DiPippo. Geothermal Power Plants, Second Edition: Principles, Applications, Case Studies and Environmental Impact. Publication Date: January 2, 2008. ISBN-10: 0750686200. ISBN-13: 978-0750686204. Edition: 2. P. 520. (≅110$)
4. Yogesh Jaluria. Design and Optimization of Thermal Systems, Second Edition (Dekker Mechanical Engineering). Publication Date: December 13, 2007. ISBN-10: 0849337534. ISBN-13: 978-0849337536. Edition: 2. P. 752. (≅200$).
5. Ali Keyhani. Design of Smart Power Grid Renewable Energy Systems. Publication Date: August 2, 2011. ISBN-10: 0470627611. ISBN-13: 978-0470627617. Edition: 1. P. 592. (≅110$).
6. Murari Singh, George Lucas. Blade Design and Analysis for Steam Turbines. Publication Date: March 24, 2011. ISBN-10: 0071635742. ISBN-13: 978-0071635745. Edition: 1. P. 384. (≅80$).
7. Alexander Leyzerovich. Wet-Steam Turbines for Nuclear Power Plants. Publication Date: April 1, 2005. ISBN-10: 1593700326. ISBN-13: 978-1593700324. P. 413. (≅130$).
8. Meherwan P. Boyce Fellow American Society of Mechanical Engineers (ASME USA) and Fellow The Institute of Diesel and Gas Turbine Engineers (IDGTE U.K.). Gas Turbine Engineering Handbook, Fourth Edition. Publication Date: December 26, 2011. ISBN-10: 0123838428. ISBN-13: 978-0123838421. Edition: 4. P. 1000. (≅110$).
POWER ENGINEERING INSTITUTE
Computer Technologies for Design of Thermal and Nuclear Power Plants
9. Heinz P. Bloch. Steam Turbines: Design, Application, and Re-Rating. Publication Date: September 8, 2008. ISBN-10: 007150821X. ISBN-13: 978-0071508216. Edition: 2. P. 414. (≅50$).
10. Gilberto Francisco Martha de Souza (Editor). Thermal Power Plant Performance Analysis (Springer Series in Reliability Engineering). - Springer; 2012 edition (January 4, 2012).- 295 p. (≅155$)
11. Drbal L.F., Boston P.G., Westra K.L., Erickson R.B. Power Plant Engineering. – Berlin: Springer, 1995. – 880 p. (≅363$)
12. Saravanamuttoo H.I.H., Rogers G.F.C., Cohen H., Straznicky P.V. Gas Turbine Theory. – England: Prentice Hall, 2008. – 592 p. (≅134$)
13. Boyce M.P. Gas Turbine Engineering Handbook. – Elsevier, 2006. – 939 p. (≅110$) 14. Versreeg H., Malalasekera W. An Introduction to Computational Fluid Dynamics: The Finite Volume
Method (Second Edition). – England: Prentice Hall. – 2007. (≅92$) 15. Smits A.J., Lim T.T. Flow visualization: Techniques and Examples. – London: Imperial College Press,
2000. – 398 p. (≅140$) 16. Jaluria Y., Torrance K.E. Computational Heat Transfer (Second Edition). – New York: Taylor & Francis,
2002 – 545 p. (≅196$) 17. Jaluria Y. Design and Optimization of Thermal Systems (Second Edition). – New York: CRC Press,
2002 – 723 p. (≅189$) 18. Incropera F.P., DeWitt D.P., Bergman T.L., Lavine A.S. Introduction to Heat Transfer.– John Wiley &
Sons, 2006. P. 912. (≅170$). 19. Jack Holman. Heat Transfer. – Mcgraw-Hill, 2009. P. 752. (≅170$).
Рurchased books
POWER ENGINEERING INSTITUTE
Computer Technologies for Design of Thermal and Nuclear Power Plants
20. Yunus Cengel and Afshin Ghajar. Heat and Mass Transfer: Fundamentals and Applications + EES DVD for Heat and Mass Transfer. – 2010. P. 928. (≅170$).
21. Conjugate Problems in Convective Heat Transfer by A. Sh Dorfman (Aug 26, 2009) P. 456. (≅145$). 22. Gas Turbine Heat Transfer and Cooling Technology by Je-Chin Han, Sandip Dutta and Srinath Ekkad
(Mar 22, 2001) P. 662. (≅200$). 23. Donatello Annaratone. Engineering Heat Transfer. Publication Date: December 17, 2009. ISBN-10:
3642039316. ISBN-13: 978-3642039317. Edition: 1st Edition.. P. 342. (≅170$). 24. T. W. Fraser Russell, Anne S. Robinson and Norman J. Wagner. Mass and Heat Transfer: Analysis of
Mass Contactors and Heat Exchangers (Cambridge Series in Chemical Engineering). Publication Date: February 11, 2008. ISBN-10: 0521886708. ISBN-13: 978-0521886703. Edition: 1. P. 402. (≅90$).
25. Ian Hore-Lacy, Stephen Tarlton, Brigita Praznik. Nuclear Energy in the 21st Century: World Nuclear University Primer. Publication Date: March 1, 2010. ISBN-10: 0955078415. ISBN-13: 978-0955078415. Edition: 2nd Revised edition. P. 140. (≅35$).
26. James P. Argyriou. Nuclear Power Plants: Design and Safety Considerations (Nuclear Materials and Disaster Research). Publication Date: December 30, 2011. ISBN-10: 1614709521. ISBN-13: 978-1614709527. P. 97. (≅50$).
27. G.F. Hewitt, John G. Collier.Introduction to Nuclear Power (Series in Chemical and Mechanical Engineering). Publication Date: June 1, 2000. ISBN-10: 1560324546. ISBN-13: 978-1560324546. Edition: 2. P. 304. (≅170$).
Рurchased books
POWER ENGINEERING INSTITUTE
Computer Technologies for Design of Thermal and Nuclear Power Plants
28. Peter G. Hessler. Power Plant Construction Management: A Survival Guide. Publication Date: October 5, 2005. ISBN-10: 1593700296. ISBN-13: 978-1593700294. P. 345. (≅80$).
29. Mike Tooley BA Advanced Technological and Higher National Certificates Kingston University. Design Engineering Manual. Publication Date: November 30, 2009. ISBN-10: 1856178382. ISBN-13: 978-1856178389. Edition: 1. P. 736. (≅130$).
30. Peter Gevorkian. Large-Scale Solar Power System Design (GreenSource): An Engineering Guide for Grid-Connected Solar Power Generation (McGraw-Hill's Greensource). Publication Date: April 22, 2011 | ISBN-10: 0071763279 | ISBN-13: 978-0071763271 | Edition: 1. P. 704. (≅90$).
31. Yogesh Jaluria. Design and Optimization of Thermal Systems, Second Edition (Dekker Mechanical Engineering). Publication Date: December 13, 2007. ISBN-10: 0849337534. ISBN-13: 978-0849337536. Edition: 2. P. 752. (≅200$).
32. David Ullman. The Mechanical Design Process (Mcgraw-Hill Series in Mechanical Engineering). Publication Date: February 2, 2009. ISBN-10: 0072975741. ISBN-13: 978-0072975741. Edition: 4. P. 448. (≅120$).
≅4380 $
Рurchased books
POWER ENGINEERING INSTITUTE
Bachelor or Specialist degree in Power Engineering Multi-disciplinary examination Competition
Conditions for admission to the program
Computer Technologies for Design of Thermal and Nuclear Power Plants
POWER ENGINEERING INSTITUTE
Programme Status
Computer Technologies for Design of Thermal and Nuclear Power Plants
• Approved by University Academic Council (June
1, 2012)
• Launched since September 1, 2012
• Plan to enroll 10 students
• 25 applications by July 1, 2012