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COURSE TITLE BASICS OF ELECTRICAL ENGINEERING I Code PFE203 Lecturer(s) Ivica Kuzmanić, M. Sc. College Professor with Full Tenure Year of study 1st 8 Number of credits allocated (ECTS) Igor Vujović, Ph.D., Assistant Professor Joško Novaković Collaborator(s) Course status Compulsory Teaching methods L (number of classes per 60 term) S E F 45 Percentage of elearning application COURSE DESCRIPTION Mastering of basic laws of direct electric current circles, electrostatics, and magnetism, applicable to other study courses and practical work. Physical properties of all materials used in electrical engineering devices and systems, as well as their components, are thoroughly studied. Particular attention will be Learning outcomes paid to the application of aquired knowledge and competences in the work of and competences shipboard electric devices and systems. STCW Electro technical officer: part of teaching sessions / classes 1.1.3, 1.1.9., 2.4.3, appendices 5.1.1, 5.12., 5.1.3., 1.1 Prerequisites for the course and entry competences Upon a successful mastering of this course the student is enabled to: Expected learning outcomes on the course level Define and use all the laws of direct, electrostatic, and magnetic current circuits. Analyse and calculate complex electric, electrostatic, and magnetic circuits. Plan and perform measurements in electric current circuits. (4-10 learning outcomes) Course contents elaborated in accordance with the syllabus Master all essential / relevant safety measures in working with electric current Classify electrical engineering materials Become familiar with the basic properties of different groups of electrical engineering materials Analyse the impact of the environment, operating conditions, and properties of materials upon their operating properties Explain the influence of degradation processes (corrosion, erosion, etc.) upon the material properties Basic concepts of electricity. Basic physical measurements and quantities. Physical properties of electrical engineering materials. Characteristics and application of conductors, semi-conductors, and insulators. Basic components of electric currents. Direct electric circuits. Basic laws of direct electric circuits. Application of Ohm’s and Kirchhoff’s laws. Resistors: application, types, designation. Power and work of electricity. Joule’s law. Applications: heaters, melting fuses, bimetals, electric bulbs. Shipboard lighting. Linear network calculation. Gausse’s law. Electric capacity. Capacitors (condensers): application, types, designation. Electrostatic energy. Electrostatic phenomena in nature. Shipbaord cables. Insulating material classification with respect to operating temperature. Electric current flow through gases and liquids. Primary and secondary chemical sources of electric power. Application, position, and maintenance of shipboard electric chemical sources. Basic magnetic quantities and laws. Magnets and electric magnets. Earth’s magnetism. Magnetic field effects. Classification of materials according to magnetic properties. ☒lectures ☐ independent tasks ☐ seminars and workshops ☒ multimedia Teaching methods ☒ exercises ☒ laboratory ☐ on line entirely ☐ work with supervisor ☐ miscellaneous e-learning ☐ field tasks Student obligations Student Class attendance 2,25 Research Practical work 0,5 monitoring and supervision Experimental work Paper Homework (Other) Essay Seminar paper (Other) Preliminary examinations 5,25 Oral Alt. 3 examination (Other) Written examination Alt. 4 Project (Other) Evaluation and Written and oral examinations. Students are given the opportunity to substitute assessment in class both with preliminary examinations. and final examination Title I. Kuzmanić: Brodska elektrotehnika i elektronika, Pomorski fakultet u Splitu, Split, 2006. Recommended I. Kuzmanić., I. Vujović: Osnove elektrotehnike – reading (available Zbirka riješenih zadataka, Pomorski fakultet u in library and Splitu, Split, 2005. through the media) I. Vujović, I. Kuzmanić: Repetitorij s uputama za laboratorijske vježbe iz Osnova elektrotehnike i Brodske elektrotehnike i elektronike, Pomorski fakultet u Splitu, Split, 2008. Kuzmanić I., Vlašić R., Vujović I.: Elektrotehnički materijali, Visoka pomorska škola u Splitu, Split, 2001. Supplementary reading Number of Availability copies in through other the library media 20 Web site– chosen topics 20 20 5 Web site– chosen topics Pinter, V.: Osnove elektrotehnike - knjiga prva, Tehnička knjiga, Zagreb, 3. izd., 1980. Pinter V.: Osnove elektrotehnike – knjiga druga, Tehnička knjiga, Zagreb, 3. izd., 1978. Quality assessment University questionnaire, student evidence list, Faculty surveillance. ensuring the determined learning outcomes Other (according to the proponent