MODULE DESCRIPTION Modue code Modue name Maszyny eektryczne Modue name in Engish Eectrica Machines Vaid from academic year 2012/2013 MODULE PLACEMENT IN THE SYLLABUS Subject Leve of education Studies profie Form and method of conducting casses Speciaisation Unit conducting the modue Modue co-ordinator Energetics 1 st degree (1st degree / 2nd degree) Genera (genera / practica) Fu-time (fu-time / part-time) The Department of Eectrica Machines and Mechatronic Systems Prof. Roman Nadoski, PhD hab., Eng. Approved by: MODULE OVERVIEW Type of subject/group of subjects Modue status Language of conducting casses Modue pacement in the syabus - semester Subject reaisation in the academic year Initia requirements Examination Number of ECTS credit points 5 Major (basic / major / speciaist subject / conjoint / other HES) Compusory (compusory / non-compusory) Poish 2 nd semester Summer semester (winter / summer) Eectrica Engineering, Eectronics (modue codes / modue names) Yes (yes / no) Method of conducting Lecture Casses Laboratory Project Other casses Per semester 30 30
TEACHING RESULTS AND THE METHODS OF ASSESSING TEACHING RESULTS Modue target The aim of the modue is to famiiarise students with the structure, the principe of operation, testing and measurement methods, the roe of transformers in an energy system, induction machines, synchronous and DC machines. Effect symbo Teaching resuts Teaching methods (/c//p/other) subject effects effects of a fied of study W_01 W_02 W_03 U_01 U_02 U_03 A student has fundamenta knowedge as regards appying the aws of eectromagnetism in the eectrica machine theory. A student has knowedge as regards the structure and principe of operation concerning: induction, synchronous, and DC machines. A student is acquainted with basic safety as we as expoitation principes (concerning eectrica machines). A student is abe to pan and conduct basic experimenta tests of eectrica machines according to OHS rues. A student is abe to make anaytica cacuations with the use of simpified substitution diagrams for basic work states of eectrica machines. A student is abe to present and interpret measurement resuts. K_01 A student can co-operate and work in a team / K_02 A student is aware of the impact of eectrica machines, which work in an energetic system, on the environment. Teaching contents: Teaching contents as regards ectures Lecture number 1 2 3 4 Teaching contents K_W01, K_W12 K_W02 K_W12 K_W17 T1A_W01 T1A_W03 T1A_W04 K_W12 T1A_W06 K_U01 K_U16 K_U19 K_U30 K_U16 K_U10 T1A_U08 T1A_U11 T1A_U07 K_U16 T1A_U09 K_K01 K_K04 T1A_K01 T1A_K03 / K_K02 T1A_K02 Transformers: their structure and principe of operation, no-oad state, shortcircuit condition, and oad state substitute diagrams, characteristics, measurements, equations, and phasors. Transformer motion properties with a oad: externa characteristics and votage variation. Three-phase transformers: their structure, connection system. Parae work of three-phase transformers. Losses and efficiency of three-phase transformers. Induction machines: their structure and principe of operation, substitute diagram, basic equations, no-oad state, short-circuit condition and work with a oad. 5 Induction machines: motion characteristics. Power and osses baance, torque. teaching resuts for a modue 6 Wound-rotor and squirre-cage motors. The reguation of rotationa veocity
7 8 9 10 11 12 13 14 through the foowing: change of votage and power suppy frequency, the number of pairs of poes, and resistance change in motor capacity. The structure and principe of operation of a synchronous unsaturated machine, phasors concerning a generator with an active-induction and activecapacity oad, votage equations. Motion properties of a generator co-operating with a stiff grid (U = const., f = const.) oaded with a fixed vaue of rea power (P = cont.) with variabe current of a fied magnet (excitation current = var.) Motion characteristics concerning a synchronous motor suppied with a fixed network oaded with a fixed shaft moment with variabe current concerning a fied magnet. Anguar characteristics of a synchronous motor, overoad capacity with a synchronous machine moment, and power ange. Synchronous motors run. A synchronous compensator: a substitute diagram, and a phasor. The structure and principe of operation, the winding of a DC machine. Motion properties of a separatey excited generator: a substitute diagram, and externa characteristic. Motion characteristics of a separatey excited DC motor: basic equations determining an eectromagnetic moment, rotationa veocity as we as a magnetic stream, a substitute diagram and mechanica characteristics, moment characteristic of a separatey excited motor, the reguation of rotationa veocity. A DC series motor: a substitute diagram, a mechanica characteristic, moment characteristic of a series motor, and the reguation of motor veocity. Permanent Magnet Direct Current Brushess Motor (PMBLDC) its structure and principe of operation; a review of construction soutions, and the structure of an eectronic commutator. Veocity and anguar position converters: their structure and principe of operation, work characteristics. 15 A fina test. Teaching contents as regards aboratory casses Laboratory cass number Teaching contents 1,2 The measurements and testing methods as regards eectrica machines. 3 Testing a three-phase transformer. 4 Parae work of three-phase transformers. 5 Testing a squirre-cage induction motor. 6 Testing an induction wind-rotor motor. 7 Testing a synchronous motor. 8 Testing a synchronous generator. 9 Testing a series DC motor. teaching resuts for a modue
10 Testing an externay-excited DC motor. 11 Testing a DC generator. 12 Testing a Permanent Magnet Direct Contro Brushess Motor (PMDCBM). 13 Testing anguar veocity converters tachometric generators and encoders. 14 Testing anguar position converters anguar position converter, sesyns. 15 A fina test. The methods of assessing teaching resuts Effect symbo W_01 W_02 W_03 U_01 U_02 U_03 K_01 K_02 Methods of assessing teaching resuts (assessment method, incuding skis reference to a particuar project, aboratory assignments, etc.) STUDENT S INPUT ECTS credit points Type of student s activity Student s workoad 1 Participation in ectures 30 2 Participation in casses 3 Participation in aboratories 30 4 Participation in tutorias (2-3 times per semester) 2 5 Participation in project casses 6 Project tutorias 7 Participation in an examination 2 8 9 Number of hours requiring a ecturer s assistance 64 (sum) 10 Number of ECTS credit points which are aocated for assisted work 2.56 11 Unassisted study of ecture subjects 10 12 Unassisted preparation for casses 13 Unassisted preparation for tests 10 14 Unassisted preparation for aboratories 11 15 Preparing reports 10
16 Preparing for a fina aboratory test 10 17 Preparing a project or documentation 18 Preparing for an examination 10 19 Preparing questionnaires 20 Number of hours of a student s unassisted work 61 (sum) 21 Number of ECTS credit points which a student receives for unassisted work 2.44 22 Tota number of hours of a student s work 125 23 ECTS credit points per modue 1 ECTS credit point=25-30 hours 5 24 Work input connected with practica casses Tota number of hours connected with practica casses 85 25 Number of ECTS credit points which a student receives for practica casses 3.4