1-4 M BH10A1600 Energy Technology Project Work INT 16-INT 17

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1 SPRING SEMESTER 2017 NOTE! Period Study level ECTS cr Course number Course Suggest topic(s) in the online application 3-4 M1 5 BH70A0101 Advanced Modeling Tools For Transport Phenomena 3 M2 3 BH30A1801 Nuclear Reactor Physics Analyses 1-4 M BH10A1600 Energy Technology Project Work INT 16-INT 17 M1 3 BH30A2200 Experimental Nuclear Thermal Hydraulics 3 M1 3 BH30A1900 Thermal Hydraulics of Nuclear Power Plants 3-4 M2 4 BH40A1500 Turbulence Models INT. = intensive course Period 1-4 = course is arranged twice a year unless otherwise informed B1 = 1 st year Bachelor M1 = 1 st year Master M1-2 = 1 st and 2 nd year Master M2 = 2 nd year Master Preliminary course descriptions on pages 2-5. See final course descriptions in Study Guide in Uni portal (June 2016). Learning agreement is created in Mobility-Online system during application process. More information about applying, i.e. Guide for Applicants, is available on > Apply to LUT > Exchange studies Course registration is done online before the semester start. Method of registration and deadlines are announced in Uni portal (Studies and services > Enrolment > Course registration) Course schedules are published in Uni portal in July (5)

2 BH70A0101 ADVANCED MODELING TOOLS FOR TRANSPORT PHENOMENA 5 ECTS cr Year and Period M.Sc. (Tech.) 1 Period 3-4 Docent, D.Sc. (Tech.) Payman Jalali Person in Charge: Professor, D.Sc. (Tech.) Timo Hyppänen Transport phenomena are dealing with the heat, mass and momentum transfer in engineering and science. In this course, advanced modeling tools and methods are introduced for students of energy technology and other departments with related background in heat transfer and fluid dynamics. Students will learn how the related computer packages such as FLUENT, COMSOL Multiphysics and MATLAB can be used to solve and analyze heat transfer and fluid flow problems using computational fluid dynamics (CFD). This course provides a mathematical basis for problem formulation, and coding/solving using the above-mentioned computational packages. Students will learn how to solve simple transport problems using their own codes in MATLAB. Then more complex problems will be taught to solve using COMSOL and FLUENT packages. Upon completion of this course, they will be able to start working on various topics in heat and fluid flow engineering for advanced designs or analysis. Introduction to transport phenomena and related problems, feeding problems into CFD algorithms and methods (discretization of equations and domains, transforming differential equations into algebraic equations etc.), diffusion and convection equations solved by finite difference and finite volume methods, complexities due to property variation, geometry and boundary conditions, application of computational packages (such as MATLAB, FLUENT, COMSOL Multiphysics etc.) in solving transport phenomena problems. The course is related to sustainability. Modes of Study 3rd period: 12 h of lectures, 12 h of exercises. 4th period: 12 h of lectures, 12 h of exercises. 3-6 homeworks and 2 projects. Total workload 130 h. 0-5; examination 40%, homeworks and projects 60%. Study materials J.D. Anderson: Computational Fluid Dynamics, McGraw-Hill, Inc D.A. Anderson, J.C. Tannehill, R.H. Pletcher: Computational Fluid Mechanics and HeatTransfer, McGraw-Hill, Inc J.H. Ferziger, M. Peric: Computational Methods for Fluid Dynamics, Springer-Verlag C. Hirsch: Numerical Computation of Internal and External Flows, Volume 1: Fundamentals of Numerical Discretization, John Wiley & Sons, MATLAB user manual. FLUENT user manual. COMSOL Multiphysics manual. Moodle Basic knowledge on programming using MATLAB or any other language. Basic Fluid Mechanics and Heat Transfer courses passed. Further Information This course has 1-10 places for open university students. More information on the web site for open 2(5)

3 BH30A1800 APPLIED REACTOR PHYSICS 3 ECTS cr Year and Period M.Sc. (Tech.) 2 Period 3 Visiting lecturers. Upon completion of the course the students 1. understands the deterministic reactor physics calculation system: transport codes for fuel bundle calculations and nodal methods for whole core calculations, 2. knows the limitations in In-Core Fuel Management work, 3. can carry out simple Monte-Carlo calculations of reactor physics. Different calculation methods of reactor physics for different purposes. Modes of Study 3rd period: 12 h of lectures, 10 h of tutorials, 4 h of computer calculations, 8 h preparation for tutprials, preparation for examination 41 h and written examination 3 h. Total workload 78 h. Study materials Moodle in use. Reuss: Neutron Physics, Duderstadt & Hamilton: Nuclear Reactor Analysis, Stacey: Nuclear Reactor Physics, where applicable. BH30A0300 Nuclear Engineering II, BH30A1700 Nuclear Reactor Physics, or BH30A1401 Nuclear Engineering and BH30A2101 Introduction to Reactor Physics. BH10A1600 ENERGY TECHNOLOGY PROJECT WORK 2-30 ECTS cr The course is mainly intended for foreign visiting students. The students register for the course by contacting the supervisor. Year and Period M.Sc. (Tech.) 1-2 Period 1-4 Professor, D.Sc. (Tech.) Jari Backman, Professor, D.Sc. (Tech.) Timo Hyppänen, Professor, D.Sc. (Tech.) Riitta Kyrki-Rajamäki, Professor, D.Sc. (Tech.) Jaakko Larjola, Professor, D.Sc. (Tech.) Esa Vakkilainen Person in Charge: Professor, D.Sc. (Tech.) Esa Vakkilainen Upon completion of the course the student 1. will be able to apply research methodology from the different viewpoints of energy technology, 2. will be able to prepare a literature search on a limited topic, 3. will be able to prepare a research report, and 4. will have an independent attitude towards working autonomously in the field of technology. Preparation of a research report on a given subject which can be acquired from the industry. The report is premised on an extensive literature search. Modes of Study 1st 4th period: Advanced special research report or seminar paper h. Modes of study will be agreed upon with the professor responsible for the field. No contact teaching. 3(5)

4 BH30A2200 EXPERIMENTAL NUCLEAR THERMAL HYDRAULICS 3 ECTS cr Year and Period M.Sc. (Tech.) 1 INT 16- INT 17 Professor, D.Sc. (Tech.) Juhani Hyvärinen, Postdoctoral Researcher, Arto Ylönen, Research Scholar, M.Sc. (Tech.) Vesa Riikonen, Researcher, M.Sc. (Tech.) Antti Räsänen, Doctoral Student, M.Sc. (Tech.) Otso-Pekka Kauppinen Upon completion of the course the students will be able to: 1. describe basic measurement techniques for one- and two-phase flows, 2. understand similitude and scaling, 3. understand thermal-hydraulic phenomena occurring in nuclear reactors and containments, in normal and abnormal operating conditions, 4. understand the interaction between experiments and code calculations, 5. describe advanced flow structure mapping techniques (e.g. wire mesh sensing, particle image velocimetry). Temperature, pressure, pressure drop, liquid level and flow measurement techniques. Void fraction measurement. Similitude, scaling laws. Models for phenomena such as critical flow, dryout, reflooding and rewetting, natural circulation, counter-current flow, two-phase flow instabilities in pipes and pools, heat transfer in tube bundles, loop seal behaviour, direct contact condensation. Designing experiments for computer code validation. Advanced flow structure measurement techniques. Modes of Study Week 16: 12 h of lectures, 12 h of tutorials, 8 h of laboratory demonstrations and exercises, independent study 8 h. Week 17: 8 h of lectures, 8 h of tutorials, 8 h of laboratory demonstrations and exercises, 4 h of computer calculations, preparation for the examination 7 h and written examination 3 h. Total workload 78 h. Study materials Moodle in use. Ghiaasian: Two-Phase Flow, Boiling and Condensation, as applicable. BH30A0300 Nuclear Engineering II or BH30A1401 Nuclear Engineering. BH30A1900 THERMAL HYDRAULICS OF NUCLEAR POWER PLANTS 3 ECTS cr Year and Period M.Sc. (Tech.) 1 Period 3 Professor, D.Sc. (Tech.) Juhani Hyvärinen, Postdoctoral Researcher, Arto Ylönen, Doctoral Student, M.Sc. (Tech.) Otso-Pekka Kauppinen Upon completion of the course the students will be able to 1. understand one-dimensional fluid flow, heat transfer, boiling and condensation in pipelike geometry, 2. master the basic continuity and constitutive equations for two-phase flow thermal hydraulics, 3. utilise the basic equations in manual calculations, 4(5)

5 Modes of Study Study materials Further Information 4. understand the basic equations used in computer models, and 5. demonstrate basic knowledge about the system codes (APROS/TRACE). The normal use, as well as the thermo hydraulic phenomena in disturbance and accident situations, of the reactor circuit and containment of a nuclear power plant. Continuity equations, closure laws, phenomenological models for phase interactions. Two-phase flow calculations. Short introduction to the use of APROS and TRACE software. 3rd period: 12 h of lectures, 12 h of tutorials, 4 h of computer calculations, preparation for examination 47 h and written examination 3 h. Total workload 78 h. Moodle in use. Todreas, Kazimi: Nuclear Systems I & II, where applicable. Winterton: Thermal Design of Nuclear Reactors, where applicable. Wallis: One-dimensional Two-phase flow. BH30A0300 Nuclear Engineering II. This course has 1-5 places for open university students. More information on the web site for open BH40A1500 TURBULENCE MODELS 4 ECTS cr Year and Period M.Sc. (Tech.) 2 Period 3-4 Docent, D.Sc. (Tech.) Teemu Turunen-Saaresti Upon completion of the course the student will be able to recognize the characteristics of turbulence models and to estimate the suitability of different turbulence models for various fluid mechanical problems. In addition, the student will be able to interpret the physical basis and the theory of turbulence models. Navier-Stokes equations, RANS equations, eddy viscosity, algebraic, one equation and two equation models, Reynolds stress model and Large Eddy Simulation. This course is also suitable for postgraduate students. Modes of Study 3rd period: 12 h of lectures, 12 h of tutorials 4th period: 12 h of lectures, 12 h of tutorials. Homework 36 h, preparation for the exam 16 h, written examination 3 h. Total workload 103 h. 0-5; examination 50%, homework 50%. Study materials David C. Wilcox: Turbulence models for CFD. Noppa portal (noppa.lut.fi) BH70A0001 Numerical Methods in Heat Transfer 5(5)