Spring- Fundamentals of Formation of Engineering Materials
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Spring- Fundamentals of Formation of Engineering Materials
Institute of Engineering Materials and Biomaterials Z1-PU7 COURSE DESCRIPTION 1. Course title: FUNDAMENTALS OF FORMATION OF ENGINEERING MATERIALS PROPERTIES 3. Validity of course description: 2013-2016 WYDANIE N1 Strona 1 z 2 2. Course code ENG/CMS, NAN, ME/EVEN/I/2/3 4. Level of studies: BSc programme / MSc programme 5. Mode of studies: intramural studies / extramural studies 6. Field of study: LLP-ERASMUS – APPLIED COMPUTER SCIENCE AND (FACULTY SYMBOL) RMT COMPUTATIONAL MATERIALS SCIENCE, MATERIALS ENGINEERING, NANOTECHNOLOGY AND MATERIALS PROCESSING TECHNOLOGY 7. Profile of studies: general academic, practical 8. Programme: all 9. Semester: summer (PACKAGE 2) 10. Faculty Unit teaching the course: Institute of Engineering Materials and Biomaterials 11. Course instructor: full professor, associate professor, senior lecturer, assistant professor 12. Course classification: common course, specialization courses, other 13. Course status: compulsory /elective, other elective in package only 14. Language of instruction: English 15. Pre-requisite qualifications: Fundamentals of materials science 16. Course objectives: The aim of the course is to formulate terms, familiarize with principles and systematize knowledge on engineering materials selection, training methods of problem solving in the field of design, familiarization with practical applications of engineering materials in electronics, biomedical, automotive and shipbuilding, chemical and air industry, training of skills of finding sources, information and combine information from new skills acquired during classes, synthesizing knowledge about materials to practical and functional applications, developing and practicing skills of using characterization sheets of engineering materials. 17. Description of learning outcomes: No. W01 W02 W03 U01 U02 U03 K01 K02 Learning outcomes description A student has detailed knowledge about the basis of material science metal, ceramic, polymer and composite materials, including nanostructural ones A student has detailed knowledge of the basis of formation of structure and properties of engineering materials: metal, ceramic, polymer and composite materials, including nanostructural ones and materials processing technology A student has detailed knowledge of materials processing technology to produce materials and products as well as product formation, their structure and properties through plastic processing, thermal, thermo-plastic treatments A student can obtain information from literature, databases and other sources, integrate them, make their interpretations, draw conclusions and formulate opinions A student is able to work independently and in a team A student can provide a written documentation of research results in nanotechnology and materials processing technologies A student can understand the need for continuous training - raising professional and personal competence A student is aware of the responsibility for collaborative tasks related to a teamwork Method of assessment Teaching methods Learning outcomes reference code Written exam Lecture T1A_W04_nitpm_0 1 Written exam Lecture + Labs T1A_W04_nitpm_0 3 Written exam Lecture + Labs T1A_W04_nitpm_0 5 Written exam Lecture + Labs T1A_U01_nitpm_01 Evaluation report Labs T1A_U02_nitpm_01 Evaluation report Labs T1A_U03_nitpm_01 Written exam Lecture + Labs T1A_K01_nitpm_01 Evaluation report Labs T1A_K03_nitpm_01 1 18. Teaching modes and hours Lecture / BA /MA Seminar / Class / Project / Laboratory 15 h lectures, 15 h labs 19. Syllabus description: Lecture: familization with mechanisms and conditions of crystallization, metal forming, cold and hot plastic deformation of metals, heat treatment of steel, thermo-chemical treatment, sintered materials, PVD and CVD processing. Materials design as an inseparable part of product engineering design - elements of engineering design, materials design, to ensure required durability of a product or its elements made from materials with required properties of engineering technology, technological design to give required properties of separate elements of a product. Aspects pf engineering design influencing a selction of materials for products and their components - functional aspects of engineering design, product life cycle analysis. Labs: surface layers, coatings, sintered tool materials, plastic deformation and recrystallization, heat treatment, composites 20. Examination: YES, NO 21. Primary sources: 1. Dobrzański L.A.: Metalowe materiały inżynierskie, WNT, Warszawa 2004 2. Dobrzański L.A.: Podstawy nauki o materiałach i metaloznawstwo, Materiały inżynierskie z podstawami projektowania materiałowego, WNT, Warszawa 2002 3. Dobrzański L.A.: Metaloznawstwo z podstawami nauki o materiałach, WNT, Warszawa 1999 4. Ashby M.F., Jones D.R.H.: Materiały inżynierskie. Tom 1 i 2, WNT, Warszawa 1997 5. Hetmańczyk M.: Podstawy nauki o materiałach, Wydaw. Politechniki Śląskiej, Gliwice 1996 22. Secondary sources: 1. Blicharski M.: Wstęp do inżynierii materiałowej, Wydawnictwa Naukowo-Techniczne, Warszawa 2006 2. Grabski M.W., Kozubowski J. A.: Inżynieria materiałowa : geneza, istota, perspektywy, Oficyna Wydawnicza Politechniki Warszawskiej, Warszawa 2003 3. Ashby M.F.: Materiały inżynierskie, Wydawnictwa Naukowo-Techniczne, Warszawa 1997 23. Total workload required to achieve learning outcomes Lp. Teaching mode : 1 Lecture 2 Classes 3 Laboratory 4 Project 5 BA/ MA Seminar 6 Other Contact hours / Student workload hours 15/60 15/60 Total number of hours 30/120 24. Total hours: 150 25. Number of ECTS credits: 6 26. Number of ECTS credits allocated for contact hours: 3 27. Number of ECTS credits allocated for in-practice hours (laboratory classes, projects): 3 26. Comments: Approved: ………………………………………………… (date , the Director of the Faculty Unit signature) 2