Savonia UAS, School of Engineering and Technology, Kuopio [Engineering and Technology in Kuopio] S TUDY I NFORMATION P ACKAGE 2015–2016 FOR E XCHANGE S TUDENTS Savonia University of Applied Sciences School of Engineering and Technology, Kuopio Study Information Package 2015–2016 for Exchange Students 1 Savonia UAS, School of Engineering and Technology, Kuopio 2 TABLE OF CONTENT 1. WELCOME TO SAVONIA UNIVERSITY OF APPLIED SCIENCES ....................... 2 1.1 Contact Persons ....................................................................................... 3 1.2 How to apply............................................................................................ 3 2. ACADEMIC CALENDAR 2015 - 2016 ............................................................. 4 3. ORIENTATION ............................................................................................ 4 4. THE COURSES TAUGHT IN ENGLISH IN THE ACADEMIC YEAR 2015 - 2016 ... 4 1. W ELCOME TO SA V ONIA UAS, SC HOOL OF ENGIN EER IN G AND TE CHNO LOGY Savonia University of Applied Sciences is a Finnish institution of higher professional education and one of the largest universities of applied sciences in Finland offering a wide range of courses – both in Finnish and in English. Savonia University of Applied Sciences’ organisation of experts educates strong professionals in six different fields of study. Five of Savonia’s schools are located in Kuopio, North Savo, near each other. Those are Engineering and Technology and School of Design (both at Opistotie Campus) and Social Services & Health Care, Business & Administration and Tourism & Hospitality and Kuopio Academy of Music and Dance. This guide book contains the courses that are taught in English at the School of Engineering and Technology in Kuopio. These courses are provided in autumn 2015 and in spring 2016. The School of Engineering and Technology is offering a wide range of courses – both in Finnish and in English. The Degree Programmes taught in English in 2015–2016 are: Information Technology Industrial Management Mechanical Engineering Study Information Package 2015–2016 for Exchange Students Savonia UAS, School of Engineering and Technology, Kuopio 3 1.1 C O N T A CT P E R S O N S International Coordinator (School of Engineering and Technology) Ms Soile Takkunen E-mail: soile.takkunen@savonia.fi Phone: +358 44 785 6298 Departmental contact persons: Civil Engineering, Construction Management and Architecture (degree programmes taught in Finnish) Senior Lecturer Ville Kuusela E-mail: ville.kuusela@savonia.fi Environmental Technology (degree programme taught in Finnish) Senior Lecturer Pasi Pajula E-mail: pasi.pajula@savonia.fi Electrical Engineering (degree programme taught in Finnish) Senior Lecturer Juhani Rouvali E-mail: juhani.rouvali@savonia.fi Energy Engineering (degree programme taught in Finnish at Varkaus Campus) Senior Lecturer Ritva Käyhkö and Senior Lecturer Olli-Pekka Kähkönen E-mail: ritva.kayhko@savonia.fi, olli-pekka.kahkonen@savonia.fi Industrial Management Senior Lecturer Jarmo Pyysalo E-mail: jarmo.pyysalo@savonia.fi Information Technology Senior Lecturer Arto Toppinen and Lecturer Pekka Granroth E-mail: arto.toppinen@savonia.fi, pekka.granroth@savonia.fi Mechanical Engineering and Production Technology (degree programme including courses taught in English) Lecturer Anssi Suhonen E-mail: anssi.suhonen@savonia.fi 1.2 H OW T O A PPLY See: http://portal.savonia.fi/amk/en/about-savonia/international-cooperation/studentexchange/incoming-student-exchange/information Student exchanges are always based on agreements between institutions – e.g. an Erasmus+ or a bilateral agreement. If you are interested in studying as an exchange student at Savonia UAS’ School of Engineering and Technology, please contact your home institution's International Coordinator first to find out more about the student exchange and its options. Savonia UAS’ International Student Services (Mobility Online application process) Student Advisor Laila Seppänen E-mail : mobility@savonia.fi Study Information Package 2015–2016 for Exchange Students Savonia UAS, School of Engineering and Technology, Kuopio 4 2. A CADEM IC CA LENDAR 2 01 5–20 16 The academic year is divided into four study periods. Each study period has its own timetable. Student exchange is always either a full academic year or one semester. Orientation (compulsory): 31 August 2015 Autumn semester: 1 September–18 December 2015 Autumn break: 12–16 October 2015 _____________________________ Spring semester: 7 January–3 June 2016 (orientation during the first day) Winter break: 7–11 March 2016 3. OR IENTATION After the application process, information packages are sent to all accepted exchange students. The orientation before the start of the studies covers e.g. Introduction to Finland Introduction to Kuopio Introduction to Savonia UAS studies Library services, computers Documents concerning the exchange 4. TH E COURSES TA UGHT IN ENGLISH IN TH E ACADEMI C Y EAR 20 15–2 016 EI13 INDUSTRIAL MANAGEMENT (3rd year studies) Autumn semester 2015 Code Course 4 EIB3203 Energy Technology 4 EIB3303 Transportation and Forwarding 4 EID4302 Quality Management and Engineering Spring semester 2016 Code 4 4 4 4 JDB3151 EID4300 EID4301 EID4401 Course International Business Operations Manufacturing Automation Development of Manufacturing Systems Environmental Technology ECTS 3 3 4 ECTS 3 4 4 4 Study Information Package 2015–2016 for Exchange Students Savonia UAS, School of Engineering and Technology, Kuopio 5 EF12 INFORMATION TECHNOLOGY (only 4th year studies!) Autumn semester 2015 Code Course 4 EFJ0100 Profitability and Investments 4 EFJ0120 Management Skills 4 EFC0120 Environmental Measurements 4 EFC0130 ICT-Services and RDI 4 EFN0200 Wireless Technologies 4 EFE0500 Microsensors and Mechanics 4 EFE0320 4 EFW0100 4 EFP6330 Sensor Signal Processing Project Distributed Programming Autumn 2015 or spring semester 2016 Code Course 4 EFS0210 Practical Training 1 4 EFS0220 Practical Training 2 4 EFS0230 Practical Training 3 ECTS 3 3 3 3 3 3 3 3 3 ECTS 6 12 12 EK13 MECHANICAL ENGINEERING, APPLIED MECHANICS (3rd year studies) Autumn semester 2015 Code 4 EKF8400 4 EKM8200 4 EKJ0012 4 4 4 4 4 EKA0041 EKA0052 EKJ0100 EKN0023 EKZ0812 Course Physics 4 Mathematical Tools in Mechanical Engineering Design of Machine Parts Dynamics FEA/FEM Modulations and Mass Customization Control Systems and Field Buses Product Development Project ECTS 3 5 5 4 4 3 4 2 COUR SE CONT ENTS OF M ECHA NI CAL ENGI NEERIN G, A PPLIED M ECHA NICS EKF8400 Physics 4 (3 ECTS) Objectives The student gains knowledge of harmonic vibrational theory and also understands the damped and forced vibration principles. He/she understands the connection between the oscillation and wave motion and knows the intensity and intensity-level concepts as well as interference and doppler effects, especially in the case of sound. The student should know the laws governing the thermal radiation. They will be familiar with the postulates underlying the general relativity and be able to treat the relativity of time, length, and velocities. The student should know the form of relativistic energy and momentum. They will know the photon photoelectric effect and the description of the wave nature of particles with non-zero mass. They will be able to apply the Bohr Model to the energetics of the one-electron atoms. The student will show Study Information Package 2015–2016 for Exchange Students Savonia UAS, School of Engineering and Technology, Kuopio 6 understanding of the structure of an atomic nucleus. In addition, the student will be familiar with the different nuclear-decay modes and will be able to apply the radioactive decay law. Content • Mechanical vibrations: harmonic vibrations, damped and forced oscillation, Waves • Sound mechanics: intensity and the intensity of the sound level, Doppler effects, Interference • Thermal radiation: Black-body Radiation, Stefan-Boltzman Law • Special Relativity: Time Dilation and Lorentz Contraction, Relativistic Energy and Momentum, The Addition of the Velocities • Photoelectric Effect • de Broglie Wavelength • The Bohr Model of a Hydrogen-Like Atom: Energy Spectrum, Transitions Nuclear Physics: The Structure of a Nucleus and the Nuclear Forces, The Mass Defect and the Binding Energy, Radioactivity Methods The course includes lessons and exercises, which will be done on students own time. During the lesson the theory of physical phenomena will be presented as well as computational management and general and specific technical applications in mechanical engineering. Completion of the course requires self-motivated familiarization to the course topics through lecture notes, course book and the exercises given by the lecturer. Grading Scale Excellent (5), Very good (4), Good (3), Satisfactory (2), Sufficient (1), Failed (0) Course Material To be announced in the beginning of the course. EKM8200 Mathematical Tools in Mechanical Engineering (5 ECTS) Objectives The student deepens the mathematical capacity in mechanical engineering’s applications. The main objective of the course is to learn how to use matrix computations, integral transformations (Laplace transform) and vector valued functions. The content of the course may partially differ depending on the needs of the applications. Content • Laplace transform • Matrix computations • Vector valued functions, divergence, rotor, line integral • Analytic geometry • Complex numbers Methods The course includes lessons and calculation exercises Grading Scale Excellent (5), Very good (4), Good (3), Satisfactory (2), Sufficient (1), Failed (0) Course Material To be announced in the beginning of the course. EKJ0012 Design of Machine Parts (5 ECTS) Objectives The student will know the general principles of machine design, and will be able to design and calculate statically loaded welded joints as borderline dimensioning. The student will also be able to calculate the tension and torque in screw joints. Shaft dimensions and determination of deformations will be covered. Student will learn how to calculate the lifetime of roller bearings and become familiar with the effect on lubrication conditions influencing bearing life. Study Information Package 2015–2016 for Exchange Students Savonia UAS, School of Engineering and Technology, Kuopio Content • • • • • 7 The General principles of machine design Static dimensioning of welds according to Eurocode 3 Tension determination of screw and screw joints Shaft dimensions and determination of deformations Life expectancy determination of roller bearings and effect of lubrication conditions. Bearing design and calculations. Use of KissSoft and other software in machine components design • Methods Theory lessons, more advanced guided exercises to deepen the theory and independent work is combined into a flexible entity. The course includes combined theory and practice lessons, as well as assignments, which are made as team work. The course passing requirement is the execution of course assignments, as well as passing intermediate tests or final exam. Grading Scale Course completion is assessed by partial and/or full exam and assignments (scale 0 - 5, weighting of 40%) and practical work (scale 0 - 5, weighting of 60%). The whole competence will be assessed on a scale of 0-5. Course Material Roloff Matek: Maschinenelemente, Eurocode 3 lesson book, SFS-EN 1993-1-1 ja SFS-EN 1993-1-8, SKF: Bearing Life Estimation, KissSoft manuals, SKF Bearing Life Calculation and lecture notes passed through Moodle EKA0041 Dynamics (4 ECTS) Objectives The student knows the basic terminology of and principles of dynamics. The student knows how to write the simple equation of motion and solve it in simple cases. The student becomes familiar with simulation of dynamics. Content • Principles of energy and momentum • Frictionless collision • Single degree of freedom vibration • Single degree of freedom vibration caused by high force • Single degree of freedom frictionless vibration caused by forced displacement • Shaft torsional vibrations • Shaft bending vibrations • Dynamics simulation Methods The course includes theory and exercise lessons as well as a course assignment. Grading Scale Excellent (5), Very good (4), Good (3), Satisfactory (2), Sufficient (1), Failed (0) Course Material Vector Mechanics For Engineers Dynamics: F. P. Beer, Jr.E.R. Johnston, W.E. Clausen, P.J. Cornwell: McGraw-Hill: 8. edition 2006 Theory and Problems of Mechanical Vibrations: S.G.Kelly: McGraw-Hill 1996 and course material passed through Moodle. EKA0052 FEA/FEM (4 ECTS) Objectives The student understands the principle of element method in strength calculations and knows how to manually calculate structure’s displacements using beam elements. The student learns the key terms used Study Information Package 2015–2016 for Exchange Students Savonia UAS, School of Engineering and Technology, Kuopio 8 in the element method and operations of how computer-aided FE- analysis is performed and is able to apply learned knowledge, as well as the ability to get more information to more demanding problems. Content • Finite element method principle • Beam elements and grids • Other general element types • Basic theory of computer aided FE-analysis: modeling of boundary conditions and forces, meshing, p- and h –method, linear and nonlinear calculations, analysis of the results • Getting to know FE-analysis software • Practical exercises and computer aided FE-analyses: loading conditions, thermal expansion, modeling of contacts, loads on 3D-models Methods The course includes theory and computer training classes as well as practical work assignment. Learning is based on students self-directed training based on the thought theory. Grading Scale Excellent (5), Very good (4), Good (3), Satisfactory (2), Sufficient (1), Failed (0) Course Material The Finite Element Method for Engineers: K., H., Huebner , E., A., Thornton and T., G., Byrom: 4. edition Wiley-Interscience 2001 and material handed out during lectures. EKJ0 10 0 M O D U L A T I O N S A N D M A S S C U S T O M I ZA T IO N (3 E C T S ) Objectives The student knows modulation and mass customization theoretical backgrounds, the student can distribute the product architecture into the product platform and verifying modules, understands the importance of module’s interfaces, as well as the differences in internal and external variability and significance in terms of cost, knows production methods suitable for mass production and product development principles. Content • Theoretical background of Modulation • Modulation methods and product families • Product platform • Modules and their interfaces • MFD-method • Theoretical background of mass customization Methods Theory lesson and the weekly of exercises that deepen the theory are combined into a flexible entity. Student’s self-motivated work in training classes and weekly exercises in emphasized in learning. Group work will be carried out through an entity incorporated with development of the classes motorcycle modulation and mass customization. Grading Scale Excellent (5), Very good (4), Good (3), Satisfactory (2), Sufficient (1), Failed (0) Course Material Material handed out during lectures. EKN0 02 3 C O N T RO L S Y ST E M S A N D F IE L D B U S E S (4 E C T S ) Obj ectives The student learns to understand the importance of programmable logic and different types of control buses in machine automation. The student becomes familiar with the different types of task solution methods, and knows how to connect the sensors, valves and actuators for control of the operational systems. The student understands the importance of logical functions in the implementation of the operations. Study Information Package 2015–2016 for Exchange Students Savonia UAS, School of Engineering and Technology, Kuopio Content • • • • • 9 Programming of stepping logic Programming of programmable logic to various types of tasks The use of task sequence and operation charts in given assignments Bus structures and their properties (SPI, CAN, Profibus, Profinet) Switching Methods The theory lessons and advanced group work as well as personal training are combined into a unified entity. The key to learning is the student’s ability to come up with control solutions from given problems based on the taught theoretical knowledge. Management of the entity as a whole requires, in addition to the device programming and coupling, as well as the intelligent deletion of the first error. The laboratory works are of key importance to learning. The course includes theory lessons and compulsory laboratory work, as well as a two personal practical works. Grading Scale Excellent (5), Very good (4), Good (3), Satisfactory (2), Sufficient (1), Failed (0) Course Material Material handed out during lectures. EKZ0 812 P RO D U C T D E VELOPMENT P RO JE C T (2 E CTS ) Objective After completing the course the student has a holistic understanding of the product development project, its planning, implementation and reporting. The main objective for the student is to use the learned theory in a practical assignment given from industry. Content The course is mainly composed of the student's own work. Work in progress will be monitored on a weekly basis by using the project journal, and weekly reviews. Project control will be handled through Moodle. The course has the following contents: • Project planning • Project execution • Project reporting • Project presentations Methods During the course the students complete a group work of a simple product’s product development project given by either the industry or the University. The students will have to integrate and put into use the competences and the knowledge built up in the product development curriculum. Grading Scale Excellent (5), Very good (4), Good (3), Satisfactory (2), Sufficient (1), Failed (0) Study Information Package 2015–2016 for Exchange Students
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