MODULE DESCRIPTION Module code Module name Module name in English Valid from academic year 2013/2014 MODULE PLACEMENT IN THE SYLLABUS Plazmowe technologie przemysłowe Industrial Plasma Technologies Subject Level of education Studies profile Form and method of conducting classes Specialisation Unit conducting the module Module co-ordinator Mechanics and Machine Design 1 st degree (1st degree / 2nd degree) General (general / practical) Full-time (full-time / part-time) Computer-Aided Laser and Plasma Technologies Laser Processing Research Centre of Kielce University of Technology and Polish Academy of Sciences Wojciech Żórawski, PhD, Eng. Approved by: MODULE OVERVIEW Type of subject/group of subjects Module status Language of conducting classes Module placement in the syllabus - semester Subject realisation in the academic year Initial requirements Examination Number of ECTS credit points 5 Method of conducting classes Major (basic / major / specialist subject / conjoint / other HES) Compulsory (compulsory / non-compulsory) Polish 5 th semester Winter semester (winter / summer) No requirements (module codes / module names) No (yes / no) Lecture Classes Laboratory Project Other Per semester 30 15
TEACHING RESULTS AND THE METHODS OF ASSESSING TEACHING RESULTS Module target The aim of the module is to familiarise students with the newest achievements connected with the utilisation of the plasma technology. Particular attention is drawn to the technologies concerning plasma-sprayed coatings. As part of the lecture, examples of application of the above-mentioned technologies in space and aviation technologies, and energetics will be presented. Another aim includes learning possible application of plasma technologies as well as preparing initial coating technologies. Effect symbol Teaching results Teaching methods (l/c/l/p/other) subject effects effects of a field of study W01_K WTLiP W02_K WTLiP W03_K WTLiP U-01 U13 U01_KW TLiP K01 A student has knowledge on materials utilised in product as well as technical devices manufacturing processes, which also covers the wear process during exploitation; moreover, a student knows and understands the processes concerning manufacturing machine elements and devices with the use of chipless technologies and material removal processes. A student has basic knowledge on the functions and possibilities of plasma devices as well as lasers and laser systems for material machining. A student has specialised knowledge of laser and plasma material removal process. A student has specialised knowledge on plasma and laser welding (as well as surface modification). A student is capable of obtaining information from the literature on the subject, databases, and other sources in various languages; moreover, a student can integrate the obtained information, analyse and interpret it, draw conclusions, formulate and justify his/her opinions. A student can identify and diagnose an engineering problem; in addition, a student can make specifications as regards construction requirements which are necessary to solve an engineering assignment. A student can select a laser or plasma system for the planned range of machining. A student understands and knows the possibilities of continuous education (second- and third-degree studies, post-graduate studies, and courses), which leads to raising his/her professional, personal, and social competences. K_W12 KS_W01_KWT LiP KS_W02_KWT LiP KS_K03_KWTL ip T1A_W02 T1A_W06 InzA_W01 InżA_W02 InzA_W05 InzA_W02 InzA_W02 InzA_W02 K_U01 T1A_U01 K_U13 KS_U01_KWTL ip T1A _U13 T1A _U14 InzA_U04 T1A_U03 InzA_U05 K_K01 T1A_K01 Teaching contents: Teaching contents as regards lectures Lecture number 1 Plasma definition and composition. Teaching contents teaching results for a module
2 The occurrence, properties, and types of plasma. 3 The fundamentals of plasma physics. 4 The construction of plasmotrons. 5 The classification of plasmotrons. 6 The branches and range of utilisation of plasma in technology. 7 The technologies of plasma cutting. 8 Plasma welding method characteristics. 9 The technology of plasma welding. 10 Plasma pad welding materials, the properties of coating, and their
applications. 11 Plasma spraying. 12 The properties of thermally-sprayed coating and the applied materials. 13 The application of thermal spraying. 14 15 Additional devices and materials used during the application of plasma (sandblasting machines, manipulators, and robots). OHS regulations and protective clothing concerning work with plasma devices. Teaching contents as regards lectures Laboratory class number 1 Introduction and OHS training. 2 Teaching contents The influence of abrasive blasting machining on the surface geometrical structure. teaching results for a module
3 Qualitative and economic analysis of plasma and laser cutting. 4 The impact of parameters on the quality of cutting with air plasma. 5 6 Determining coating efficiency in the distance function concerning spraying in supersonic spraying. Analysing the influence of plasma spraying parameters on abrasive wear of Cr 2 O 3 coatings. 7 Phenomena occurring in the microstructure of plasma-sprayed coating after laser machining. The methods of assessing teaching results Effect symbol Methods of assessing teaching results (assessment method, including skills reference to a particular project, laboratory assignments, etc.) STUDENT S INPUT ECTS credit points
Type of student s activity Student s workload 1 Participation in lectures 30 2 Participation in classes 3 Participation in laboratories 15 4 Participation in tutorials (2-3 times per semester) 6 5 Participation in project classes 6 Project tutorials 7 Participation in an examination 8 Participation in a final test on laboratory classes 9 Number of hours requiring a lecturer s assistance 51 (sum) 10 Number of ECTS credit points which are allocated for assisted work (1 ECTS credit point=25-30 hours) 2 11 Unassisted study of lecture subjects 45 12 Unassisted preparation for classes 13 Unassisted preparation for tests 10 14 Unassisted preparation for laboratories 10 15 Preparing reports 10 16 Preparing for a final laboratory test 17 Preparing a project or documentation 18 Preparing for an examination 19 Preparing questionnaires 20 Number of hours of a student s unassisted work 75 (sum) 21 Number of ECTS credit points which a student receives for unassisted work (1 ECTS credit point=25-30 hours) 22 Total number of hours of a student s work 126 23 ECTS credit points per module 1 ECTS credit point=25-30 hours 5 24 Work input connected with practical classes Total number of hours connected with practical classes 0 25 Number of ECTS credit points which a student receives for practical classes (1 ECTS credit point=25-30 hours) 3 0