Faculty of Maritime Studies / MARINE ENGINEERING / MATHEMATICS I

Course:

MATHEMATICS I/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
373	Obavezan	1	5	2+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / TECHNICAL MECHANICS

Course:

TECHNICAL MECHANICS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
374	Obavezan	1	7	3+3+0

Programs	MARINE ENGINEERING
Prerequisites	None.
Aims	The aim of the course is to introduce students to the basic concepts and laws of mechanics and hydrodynamics and their application in accordance with the requirements STCW'10 Convention (Table A-III/1 and A-III/2) and IMO model course7.04 (Appendix 4) and IMO model course 7.02 (para 1.2.2.).
Learning outcomes	Upon successful completion of the course, the student will be able to: - Get a wide range of integrated theoretical and practical knowledge of rigid body mechanics and fluid mechanics, and especially from the statics and dynamics of rigid bodies and fluids that are applicable in various fields of engineering and especially in the field of Marine Engineering; - Get specific knowledge related to critical thinking and reasoning in considering and solving practical problems in the field of statics and dynamics of rigid bodies and fluids; - Master the methods of studying resting state and movement of the body and the fluid (water) under the influence of the forces and pressures based on the basic principles and laws of mechanics; - Apply methods, basic laws and principles of mechanics to the study of rest and movement of material point under the action of force, the study of body movement (translational, craft) based on the equations of motion and the basic laws, principles and theorems of rigid body mechanics and fluid mechanics (Newton's laws, D'Alamber`s principle, the theorem on the change of kinetic energy, theorem on the change of momentum, Pascal's law, the law of conservation of energy - Bernoulli's equation), and in particular on specific issues such as: periodic free and harmonic motion, balancing rotating masses, reduced speed rotation bodies rotate, the friction of hard bodies and fluid, emphasizing the fluid; - Give a critical assessment regarding developments in the analysis of the solid bodies and fluid movement during the application of the basic laws, principles and theorems of mechanics; - Recognize the importance of individual size varies mechanics (speed, acceleration, force, mass, moment of inertia, torque, pressure, kinetic, potential, and pull energy, work momentum, angular momentum, power, thrust, absolute and relative pressure) and their physical meaning; - Show the ability to independently solve specific problems of the problem of rest state and movement of the solid body and the fluid, and to the problems of sleep and movement under the force of friction and without taking into account the friction force, problems related to balancing the rotating mass, problems related to body movements, problems of computations of energy, work, power, volume and angular momentum, the problems of determining the hydrostatic pressure, problems related to the swimming body and for the study of fluid flow in the pipeline, leaking fluids problems, determining the energy losses in the power flow. - Get a wide range of integrated theoretical and practical knowledge of the mechanics of deformable bodies and especially from the resistance of materials that are applicable in various fields of engineering and especially in Marine Engineering; - Get specific knowledge related to critical thinking and reasoning in considering and solving practical problems in the field of strength of materials and structural design; - Master the calculation methods of structural components and structures composed of beams; - Apply calculation methods of beams subjected to basic types of stress, axial strain, bending, twisting, combined stresses, etc.; - Provide critical evaluation related to the analysis of stress and strain loaded body forms a beam girder - rod; - Recognize and distinguish the character of individual impact: load, body shape, type of material from which the body is made of the size of internal forces - stress and strain of the body; - Show the ability to independently calculate and optimize the beam girders loaded in different ways and structures composed of beams.
Lecturer / Teaching assistant	Prof. Goran Ćulafić, PhD, Mr Stefan Culafic
Methodology	Lectures, calculation exercises, homework assignments, consultations, tests.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Kinematics. Kinematics of point: Basic kinematics units. (IMO 7.04;4.1.2.)
I week exercises
II week lectures	Kinematics of points: Linear motion, rotating motion and harmonic motion.(IMO 7.04;4.1.2.;(IMO 7.02;1.2.2.2))
II week exercises
III week lectures	Kinematics. Translational motion of bodies. Rotation of a body about a fixed axis.(IMO 7.04;4.1.2.); (IMO 7.02;1.2.2.2); Statics (IMO 7.04;4.1.1.). Statics. Concurrent force system. Equilibrium force. system. (IMO 7.04;4.1.1.)
III week exercises
IV week lectures	Test I.
IV week exercises
V week lectures	Dynamics. Newton's laws, D'Alamber`s principle. The equation of body rotation. (IMO 7.04;4.1.2
V week exercises
VI week lectures
VI week exercises	Dynamics. Work. Power. Energy (IMO 7.04;4.1.2.) Dynamics. The dynamics of free harmonic motion. Resonance. (IMO 7.02, 1.2.2.2)
VII week lectures	Test II
VII week exercises
VIII week lectures	Dynamics. Primary and secondary forces. Primary and secondary momentum (IMO 7.02;1.2.2.1)
VIII week exercises
IX week lectures	Mechanics of fluids. Hydrostatics. Basic laws and applications. (IMO 7.04;4.1.3) Hydrodynamics. Basic laws and applications.(IMO 7.02;1.2.2.6)
IX week exercises
X week lectures	Test II
X week exercises
XI week lectures	Material resistance. Axial moment of inertia . Statical diagrams. (IMO 7.02;1.2.2.3).
XI week exercises
XII week lectures	Material resistance. Stress. Strain. Relationship between stress and strain. (IMO 7.02;1.2.2.3).
XII week exercises
XIII week lectures	Material resistance. Axial strain, Bending. (IMO 7.02;1.2.2.3).
XIII week exercises
XIV week lectures	Material resistance. Torsion. (IMO 7.02;1.2.2.3).Stresses. Deformation energy.(IMO 7.02;1.2.2.3)
XIV week exercises
XV week lectures	Test IV (Final exam)
XV week exercises

Student workload
Per week	Per semester
7 credits x 40/30=9 hours and 20 minuts 3 sat(a) theoretical classes 0 sat(a) practical classes 3 excercises 3 hour(s) i 20 minuts of independent work, including consultations	Classes and final exam: 9 hour(s) i 20 minuts x 16 =149 hour(s) i 20 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 9 hour(s) i 20 minuts x 2 =18 hour(s) i 40 minuts Total workload for the subject: 7 x 30=210 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 42 hour(s) i 0 minuts Workload structure: 149 hour(s) i 20 minuts (cources), 18 hour(s) i 40 minuts (preparation), 42 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend classes, take the tests and exam(s).
Consultations
Literature	1. G. Ćulafić: Technical mechanics, written lectures (in Montenegrin). 2. Z. Ćulafić: Strength of materials, 1996 (in Montenegrin).
Examination methods	Test II, 0-25 points; Test III, 0-25 points; Test IV (final exam), 0-25 points; Positive mark requires not less than 50 points cumulatively.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / OILS, FUEL OILS AND WATER

Course:

OILS, FUEL OILS AND WATER/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
381	Obavezan	2	3	2+0+1

Programs	MARINE ENGINEERING
Prerequisites	No special requirements for the course.
Aims	The students will be familiarized with basic properties of engine fuels, lubricants and water, as well as their application on board ships in accordance with STCW’10 (Table A-III and A-III/2) and IMO model course 7.04 (App. 5.1.1.,App. 5.1.2., App. 5.1.4, App. 5.1.5) and model course 7.02 (para 1.2.6)
Learning outcomes	Upon successful completion of the course, the student will be able to: - Define the categorisation of fuels and describe the composition and characteristics of crude oil. - Analyse basic processes in crude oil processing. - Perform the categorisation of liquid and gaseous fuels, their composition and properties. - Analyse and define the fuel combustion process. - Analyse the fuel types for shipboard use. - Analyse and explain the fuel systems on-board ships. - Define the importance of lubrication. - Define the categorisation and properties of lubricants. - Describe the types of lubricants on-board ships. - Describe the lubrication systems on-board vessels. - Analyse the use of water; define its physical and chemical properties and difficulties in its application on-board ships.
Lecturer / Teaching assistant	Prof. Danilo Nikolić, PhD, Radmila Gagić, MSc
Methodology	Lectures, seminar paper, tests, laboratory exercises, final exam, consultations, individual work.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Fundamentals of chemical reactions. (IMO 7.04; App. 5.1.1)
I week exercises	Introduction. Fundamentals of chemical reactions. (IMO 7.04; App. 5.1.1)
II week lectures	Acidity and alkalinity. (IMO 7.04; App 5.1.2)
II week exercises	Acidity and alkalinity. (IMO 7.04; App 5.1.2)
III week lectures	Introduction to fossil fuels. Crude oil. Natural gas. Coal.
III week exercises	Introduction to fossil fuels. Crude oil. Natural gas. Coal.
IV week lectures	Introduction to fuels. (IMO 7.04; App 5.1.5) Liquid and gaseous fuels: categories, structure, properties and application.
IV week exercises	Introduction to fuels. (IMO 7.04; App 5.1.5) Liquid and gaseous fuels: categories, structure, properties and application.
V week lectures	Introduction to fuels. (IMO 7.04; App 5.1.5) Physical and chemical properties of fuels (IMO 7.02; 1.2.6.1 – 2)
V week exercises	Introduction to fuels. (IMO 7.04; App 5.1.5) Physical and chemical properties of fuels (IMO 7.02; 1.2.6.1 – 2)
VI week lectures	Physical and chemical properties of fuels (IMO 7.02; 1.2.6.3 – 4)
VI week exercises	Physical and chemical properties of fuels (IMO 7.02; 1.2.6.3 – 4)
VII week lectures	Standard quality of engine fuels. Fuel systems on board ships. Fuel combustion process. Problems related to the combustion of heavy fuel oil.
VII week exercises	Standard quality of engine fuels. Fuel systems on board ships. Fuel combustion process. Problems related to the combustion of heavy fuel oil.
VIII week lectures	Test I
VIII week exercises	Test I
IX week lectures	Introduction to tribology. Introduction to lubricants.
IX week exercises	Introduction to tribology. Introduction to lubricants.
X week lectures	Marine engine oils. (IMO 7.04; App 5.1.5)
X week exercises	Marine engine oils. (IMO 7.04; App 5.1.5)
XI week lectures	Physical and chemical properties of marine oils. (IMO 7.02; 1.2.6.1 – 4)
XI week exercises	Physical and chemical properties of marine oils. (IMO 7.02; 1.2.6.1 – 4)
XII week lectures	Introduction. Use of water on board ships. Water treatments on board ships. (IMO 7.04; App 1.4)
XII week exercises	Introduction. Use of water on board ships. Water treatments on board ships. (IMO 7.04; App 1.4)
XIII week lectures	Use of water on board ships. Water treatment and quality analysis. (IMO 7.04; App 1.4)
XIII week exercises	Use of water on board ships. Water treatment and quality analysis. (IMO 7.04; App 1.4)
XIV week lectures	Use of water on board ships. Water treatment and quality analysis. (IMO 7.04; App 1.4)
XIV week exercises	Use of water on board ships. Water treatment and quality analysis. (IMO 7.04; App 1.4)
XV week lectures	Review and preparation for the final exam.
XV week exercises	Review and preparation for the final exam.

Student workload	During the semester Teaching and final exam: (4 hours) x 16 = 64 hours Necessary preparations before the semester start (administration, enrolment, verification): 2 x (4 hours and 20 minutes) = 8 hours Total hours: 3 x 30 = 90 hours Remedial classes (additional hours) for preparing the make-up exam, including the exam duration: 0 - 30 hours. Total workload structure: 64 hours (classes) + 8 hours (preparation) + 18 hours (remedial classes)
Per week	Per semester
3 credits x 40/30=4 hours and 0 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 0 excercises 1 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 4 hour(s) i 0 minuts x 16 =64 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 4 hour(s) i 0 minuts x 2 =8 hour(s) i 0 minuts Total workload for the subject: 3 x 30=90 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 18 hour(s) i 0 minuts Workload structure: 64 hour(s) i 0 minuts (cources), 8 hour(s) i 0 minuts (preparation), 18 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend classes, take the tests and exam(s).
Consultations
Literature	1. D. Nikolic, PowerPoint lectures given on the Faculty’s official website; 2. D. Nikolic, Pogonski materijali (Fuel Materials) script, Faculty of Maritime Studies, Kotor. 1. An Introduction To LNG Bunkering, Nigel Draffin, 2013 ISBN 978-1-908663-15-3,
Examination methods	Test I: 0-20 points; Test II: 0-20 points; Seminar paper: 0-10 points; Laboratory exercises: 0-15 points; Attendance: 0-5 points; Final exam: 0-30 points; Positive grade requires not less than 50 points cumulatively.
Special remarks
Comment	If needed, the subject can be thought in English.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MATHEMATICS II

Course:

MATHEMATICS II/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
384	Obavezan	2	5	2+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MACHINE ELEMENTS

Course:

MACHINE ELEMENTS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
385	Obavezan	2	3	2+1+0

Programs	MARINE ENGINEERING
Prerequisites	No prerequisites for course enrolment and attending
Aims	On the completion of this course, students would be able to design and to maintain machine elements and assemblages, considering STCW10 (A-III/1 and A-III/2,) and IMO model course 7.04.
Learning outcomes	Expected learning outcomes: Upon successful completion of this subject the student will be able to: • Describe use of different types of design criteria for machine elements. • Describe various mechanical engineering materials properties. • Describe different machine elements and their function. • Apply appropriate analytical models to describe and predict the behaviour of a variety of machine elements. • Perform reduction of the behaviour of a complex machine into appropriate sub-systems and then analyze the behaviour of their elements. • Perform selection of the appropriate machine elements for different applications. • Perform basic design of a variety of machine elements. • Apply standards to machine elements design
Lecturer / Teaching assistant	Prof.dr Janko Jovanović and Mr Draško Kovač
Methodology	Lectures, calculation exercises, homework, consultations, test

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Basic terms and classifications of machine elements.
I week exercises	Introduction. Basic terms and classifications of machine elements.
II week lectures	Strength based design. Manufacturability based design. Recycling based design.Working loading of machine elements (Loading types. Strain and stress. Stress concentracion). Static loading. Cyclic loading. Strenght and allowable stress of machine elements (Yield and ultimate stress. Endurance limit).
II week exercises	Strength based design. Manufacturability based design. Recycling based design.Working loading of machine elements (Loading types. Strain and stress. Stress concentracion). Static loading. Cyclic loading. Strenght and allowable stress of machine elements (Yield and ultimate stress. Endurance limit).
III week lectures	Preferred sizes and tolerances (Standardization. Tolerances of linear dimensions. ISO hole and shaft basis fits. Temperature influence on fits. Tolerances of form, profile, orientation, location and runout.)
III week exercises	Preferred sizes and tolerances (Standardization. Tolerances of linear dimensions. ISO hole and shaft basis fits. Temperature influence on fits. Tolerances of form, profile, orientation, location and runout.)
IV week lectures	Joints, connections and fasteners. Welded joints (Geometry, materials and quality). Calculation of welded joints.
IV week exercises	Joints, connections and fasteners. Welded joints (Geometry, materials and quality). Calculation of welded joints.
V week lectures	Welded pressure vessels. Soldering joints. Adhesive joints. Cylindrical clamp connections. Conical clamp connections. Clamping heads.
V week exercises	Welded pressure vessels. Soldering joints. Adhesive joints. Cylindrical clamp connections. Conical clamp connections. Clamping heads.
VI week lectures	Threaded fasteners (Thread profile parameters. Standard thread profiles. Bolts. Nuts. Washers. Materials. Manufacturing and surface protection. Prevention of threaded fasteners loosening)
VI week exercises	Threaded fasteners (Thread profile parameters. Standard thread profiles. Bolts. Nuts. Washers. Materials. Manufacturing and surface protection. Prevention of threaded fasteners loosening)
VII week lectures	Calculation of threaded fasteners (Axially loaded bolted joints. Transversaly laoded bolted joints. Multi-bolted joints). Joints of shafts and power-transmitting elements (Key joint. Splined shaft joints). Springs (Flexion spings. Torsion spings)
VII week exercises	The First Compulsory Test
VIII week lectures	Springs (Compression and extension springs. Rubber elastic elements) Motion-transmitting elements. Shafts and axles (Materials. Calculation)
VIII week exercises	Springs (Compression and extension springs. Rubber elastic elements) Motion-transmitting elements. Shafts and axles (Materials. Calculation)
IX week lectures	Sleeves (Axial sleeves. Cross sleeves) Slider bearings (Friction and lubrication. Types and materials. Calculation)
IX week exercises	Sleeves (Axial sleeves. Cross sleeves) Slider bearings (Friction and lubrication. Types and materials. Calculation)
X week lectures	Rolling element bearings (Types and marking system. Assemblage and lubrication. Calculation) Power-transmitting elements. Gearing transmission (Types).
X week exercises	Rolling element bearings (Types and marking system. Assemblage and lubrication. Calculation) Power-transmitting elements. Gearing transmission (Types).
XI week lectures	Gearing transmission (Basic parameters. Involute gears. Materials and manufacturing. Spur gears – Undercuting and Loading)
XI week exercises	Gearing transmission (Basic parameters. Involute gears. Materials and manufacturing. Spur gears – Undercuting and Loading)
XII week lectures	Gearing transmission (Helical gears. Bevel gears. Worm gears. Bending at the fillet of the gear tooth – working and allowable stress. Contact pressure on the flank of the gear tooth – working and allowable stress)
XII week exercises	Gearing transmission (Helical gears. Bevel gears. Worm gears. Bending at the fillet of the gear tooth – working and allowable stress. Contact pressure on the flank of the gear tooth – working and allowable stress)
XIII week lectures	Gearing transmission in the ship’s propulsion system. Belt transmission. Chain transmission.
XIII week exercises	Gearing transmission in the ship’s propulsion system. Belt transmission. Chain transmission.
XIV week lectures	Couplings (Rigid couplings. Flexible couplings. On-off couplings. Hydrodynamics couplings. Special couplings)
XIV week exercises	The Second Compulsory Test
XV week lectures	Flow elements. Pipes (Materials. Connection. Calculation). Pipe fasteners (Valves. Latches. Covers)
XV week exercises	The Additional First and Second Compulsory Tests

Student workload	Peer week 3 credits x 40/30 = 4 hours Structure: Lectures: 2 hours of lectures Exercises: 1 hour of exercises Individual work including consultation: 1 hour Per semester Classes and final exam: 4 hours x 16 weeks = 64 hours Necessary preparations before the semester start (administration, enrolment, verification): 4 hours x 2 weeks = 8 hours Total load for the subject: 3 x 30 = 90 hours Remedial classes for the corrective term, including the corrective exam: 90 hours – (64 hours + 8 hours) = 18 hours Load structure: 64 hours (Classes) + 8 hours (Preparation) + 18 hours (Remedial classes)
Per week	Per semester
3 credits x 40/30=4 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 1 excercises 1 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 4 hour(s) i 0 minuts x 16 =64 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 4 hour(s) i 0 minuts x 2 =8 hour(s) i 0 minuts Total workload for the subject: 3 x 30=90 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 18 hour(s) i 0 minuts Workload structure: 64 hour(s) i 0 minuts (cources), 8 hour(s) i 0 minuts (preparation), 18 hour(s) i 0 minuts (additional work)
Student obligations	Students are obliged to attend lectures, submit homework assignments and take final exam
Consultations	2 times per week
Literature	Vojislav Miltenović, Radoš Bulatović, Machine elements - Textbook and tables, University of Montenegro, 2007 Radoš Bulatović, Janko Jovanović, Machine elements - Workbook, University of Montenegro, 2014
Examination methods	: Four homeworks 4x4 = 16 points Attendance to lectures 4 points Two tests 2x15 = 30 points Final exam 50 points Passing mark is awarded if the student collects at least 50 points
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE STEAM BOILERS

Course:

MARINE STEAM BOILERS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
389	Obavezan	3	5	2+1+1

Programs	MARINE ENGINEERING
Prerequisites	None
Aims	Upon completion of this course, students should be able to do the conception and design of boilers of marine proulsion systems
Learning outcomes	Upon completion of this course the student will be able to: 1. Define and classify boilers and other components of marine propulsion systems 2. Analyzes and describe different devices for combustion by fuel type 3. Execute the thermal calculation of the boiler 4. Describe and calculate the basic elements of the boiler and marine propulsion 5. Analyze the influence of operating parameters on the operational characteristics of the boiler
Lecturer / Teaching assistant	Prof.dr Milan Šekularac, dipl.ing mech.eng; mr Draško Kovač, dipl.ing.mech.eng
Methodology	Lectures, exercises, projected task, consultations, field work

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction: working principle, classification of boilers, display of various design
I week exercises	Numerical problems from lectures and instruction for project design
II week lectures	Fuels and fuel combustion in steam boilers
II week exercises	Numerical problems from lectures and instruction for project design
III week lectures	Boiler combustion systems
III week exercises	Numerical problems from lectures and instruction for project design
IV week lectures	Thermal calculations of boilers
IV week exercises	Numerical problems from lectures and instruction for project design
V week lectures	Hydrodynamics of evaporating and nonevaporating heating surfaces of boiler
V week exercises	Numerical problems from lectures and instruction for project design
VI week lectures	Aerodynamics of air and gas tract of the boiler
VI week exercises	Numerical problems from lectures and instruction for project design
VII week lectures	First test
VII week exercises	Reviewing the results of the first test
VIII week lectures	Basic elements: furnaces, evaporators
VIII week exercises	Numerical problems from lectures and instruction for project design
IX week lectures	Basic elements: steam superheaters and additional superheater
IX week exercises	Numerical problems from lectures and instruction for project design
X week lectures	Basic elements: temperature control of superheated steam
X week exercises	Numerical problems from lectures and instruction for project design
XI week lectures	Basic elements: water heaters, air heaters
XI week exercises	Numerical problems from lectures and instruction for project design
XII week lectures	Water and steam. Preparation of water. Deposits on water-steam side
XII week exercises	Numerical problems from lectures and instruction for project design
XIII week lectures	Exploitation of heating surfaces. Corrosion, wearing, contamination and cleaning
XIII week exercises	Numerical problems from lectures and instruction for project design
XIV week lectures	Second test
XIV week exercises	Reviewing the results of the second test, consultations and examples
XV week lectures	The correctional test. Consultation for the final exam
XV week exercises	Consultation for the final exam

Student workload	weekly: 4,5 ECTS x 40/30 = 6 hours Structure: 2 hours lectures 2 hours exercises 2 hours self learning
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend classes and exercises, do home exercises and both tests
Consultations	After Lectures
Literature	- Brkić Lj. idr: Parni kotlovi, Mašinski fakultet, Beograd, 2009. - Brkić Lj. idr: Termički proračun parnih kotlova, Mašinski fakultet, Beograd, 2009. - Barberton O., et al.: Steam, Its Generation and Use, B & W, New York, 1998. - Skripta, Vladan Ivanović, PF Kotor
Examination methods	Tests 20% each (total 40%) Two homework assignments, each to 10 % (total 20%) and are prerequisite for final exam Final exam 40% Grading Scale: 100% - 90% A; 89% - 80% B; 79% - 70% C; 69% - 60% D; 59% - 51% E; 50% - 0% F
Special remarks
Comment	Additional information can be obtained from teacher

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE ENGINES I

Course:

MARINE ENGINES I/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
391	Obavezan	3	5	2+1+1

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / SAFETY AT SEA

Course:

SAFETY AT SEA/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
397	Obavezan	3	2	1+0+1

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
2 credits x 40/30=2 hours and 40 minuts 1 sat(a) theoretical classes 1 sat(a) practical classes 0 excercises 0 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 2 hour(s) i 40 minuts x 16 =42 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 2 hour(s) i 40 minuts x 2 =5 hour(s) i 20 minuts Total workload for the subject: 2 x 30=60 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 12 hour(s) i 0 minuts Workload structure: 42 hour(s) i 40 minuts (cources), 5 hour(s) i 20 minuts (preparation), 12 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE ENGINES II

Course:

MARINE ENGINES II/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
399	Obavezan	4	5	2+1+2

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 2 sat(a) practical classes 1 excercises 1 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARITIME LAW

Course:

MARITIME LAW/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
1547	Obavezan	1	3	2+0+0

Programs	MARINE ENGINEERING
Prerequisites	No prerequisites for course enrollment and attending
Aims	The course aims to teach students the legal regulations in the field of maritime law, in accordance with the requirements according to STCW '10 Convention and IMO model course 7.02 (Item 4.2.1) and 7.04 (Item 4.6.1).
Learning outcomes	It is expected that the student after passing the exam in relating the subject Maritime public law may: - Define, differentiate and compare the maritime zones in accordance with the Law of the Sea. - Describe the legal status of the ship in different the maritime zones. - Distinguish basic notions of maritime safety - Classify and describe the vessels. - Classify and describe certificates and other documents that should be carried out on board ships. - Describe and analyze the inspection control of ships. - Distinguish between rights and obligations of seafarers in regard to of working on board ship. - Analyze national and international regulations in regard to maritime law (Law of the Sea, Maritime Administrative Law and Maritime Labour Law).
Lecturer / Teaching assistant	PhD Jelena Nikčević, Associate Professor
Methodology	Lectures, consultations, discussions, seminar work, colloquium, the final exam, independent work.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction to Maritime Law 4.6.1.1.(IMO Model Course 7.04)
I week exercises
II week lectures	Law of the Sea 4.6.1.2. (IMO Model Course 7.04)
II week exercises
III week lectures	Protection and Preservation of the Marine Environment 4.2.1.8 (IMO Model Course 7.02)
III week exercises
IV week lectures	International Convention on Civil Liability for Oil Pollution Damage,1969 (CLC 1969) New legal regime. 4.2.1.8 (IMO Model Course 7.02)
IV week exercises
V week lectures	Maritime Administrative Law. Maritime safety. Safety ship 4.6.1.3 (IMO Model Course 7.04) International conventions relating to safety ship.
V week exercises
VI week lectures	The first compulsory assignment
VI week exercises
VII week lectures	International Convention for the Safety of Life at Sea, 1974 as amended (SOLAS) 4.6.1.3(IMO Model Course 7.04)
VII week exercises
VIII week lectures	MARPOL 73/78 as amendmanes, 4.2.1.4 (IMO Model Course 7.02) Classification Societies 4.2.1.6.5 (IMO Model Course 7.02)
VIII week exercises
IX week lectures	Safety cargo. Legal regulation relating to safe carriage of goods on board ship. 4.6.1.3 (IMO Model Course 7.04) Carriage od dangerous goods.SOLAS Chapter VII, 4.6.1.3 (IMO Mode
IX week exercises
X week lectures	Occupational safety.SOLAS Chapter IX, STCW 1978, 1995, 2010. (aims and content) 4.6.1.3 (IMO Model Course 7.04) MLC 2006. 4.2. 1.6.2. (IMO Model Course 7.02) Code of safe W
X week exercises
XI week lectures	The second compulsory assignment
XI week exercises
XII week lectures	Control of ship safety. Flag state control. Port State control. Substandard ships. 4.2.1.7 (IMO Model Course 7.02)
XII week exercises
XIII week lectures	General Average and Marine Insurance 4.2.1.6.6 (IMO Model Course 7.02) Assistance and Salvage 4.2.1.6.3 (IMO Model Course 7.02)
XIII week exercises
XIV week lectures	Charter Parties 4.2.1.6.6 (IMO Model Course 7.02) Convention on Limitation of Liability for Maritime Claims, 1976 (LLMC 1976)
XIV week exercises
XV week lectures	International Ship and Port Facility Security Code (ISPS Code) 4.6.1.3 (IMO Model Course 7.04)
XV week exercises

Student workload	Per week 4 credits x 40/30 = 5hours + 20 minutes Structure: 2 hours of lectures 1 hours of exercise 0 hours of practical work 2 hours 20 minutes of individual work, including consultations During semester Teaching and the Final Exam: 5h + 20 min. x 16 = 85h + 20 minutes Necessary preparation before Term starting (admin., enrolment, verification): 5h + 20 min x 2 = 10h + 40min Total hours for the course: 4 x 30 = 120h Additional hours for preparing correction of final exam, including the taking of the exam: 24h Structure of the students’ duties: 85h + 20 min.(lectures) + 10h + 40min + 24h (additional work)
Per week	Per semester
3 credits x 40/30=4 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 0 excercises 2 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 4 hour(s) i 0 minuts x 16 =64 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 4 hour(s) i 0 minuts x 2 =8 hour(s) i 0 minuts Total workload for the subject: 3 x 30=90 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 18 hour(s) i 0 minuts Workload structure: 64 hour(s) i 0 minuts (cources), 8 hour(s) i 0 minuts (preparation), 18 hour(s) i 0 minuts (additional work)
Student obligations	Students are obliged to attend lectures, take compulsory assignments and final exam.
Consultations
Literature	IMO RECOMMENDED LITERATURE: Textbooks: 1. Hill, C. Maritime Law, 4th ed. London, Lloyd's of London Press, 1995. (ISBN 1-850-44-888-4) 2. Maclachlan, Malcolm. - The Shipmaster‘s Business Companion (Book and CD), 4th ed, 2004. (ISBN 978-1-870077-45-3) B
Examination methods	1. Compulsory Assignment I, from 0 to 20 points. 2. Compulsory Assignment II, from 0 to 20 points. 3. Seminar paper, from 0 to 10 points. 4. Final Exam, from 0 to 50 points. Passing mark is obtained if the student cumulatively collects at least 50 po
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE INSURANCE

Course:

MARINE INSURANCE/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
1564	Izborni	5	6	3+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 3 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 3 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / PORTS AND TERMINALS

Course:

PORTS AND TERMINALS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
1566	Izborni	6	6	2+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 4 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / ENGLISH LANGUAGE I

Course:

ENGLISH LANGUAGE I/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
2586	Obavezan	1	3	2+1+0

Programs	MARINE ENGINEERING
Prerequisites	There are no special requirements.
Aims	The course aims to enable the students to successfully communicate and follow literature in English.
Learning outcomes	Upon successful completion of the course, the student will be able to: - Successfully communicate in English in general situations in accordance with the taught curriculum. - Successfully communicate in business environment in accordance with the taught curriculum.
Lecturer / Teaching assistant	Zorica Đurović, MA
Methodology	Interactive classes, exercises, everyday consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction, introduction to the subject.
I week exercises	Introduction, introduction to the subject.
II week lectures	Companies.
II week exercises	Companies. Grammar: present tenses, Present Simple.
III week lectures	Contacts:
III week exercises	Contacts: Grammar: Present Continuous Tense.
IV week lectures	Visitors.
IV week exercises	Visitors. Grammar: Questions, Simple Past Tense.
V week lectures	Employment. Vocabulary.
V week exercises	Employment. Vocabulary. Grammar: Present Perfect Tense. Comparisons
VI week lectures	Travels.
VI week exercises	Travels.Grammar: Countable and uncountable nouns. Revision, preparation for the test.
VII week lectures	Test I.
VII week exercises	Test I.
VIII week lectures	Orders.
VIII week exercises	Orders. Grammar: Future tense. Modal verbs.
IX week lectures	Entertainment.
IX week exercises	Entertainment. Grammar: Conditionals.
X week lectures	Future trends.
X week exercises	Future trends. Future predictions.
XI week lectures	Your career.
XI week exercises	Your career. Grammar: Revision of tenses
XII week lectures	Revision and preparation for the test.
XII week exercises	Revision and preparation for the test.
XIII week lectures	Test II.
XIII week exercises	Test II.
XIV week lectures	Revision and preparation for the final exam.
XIV week exercises	Revision and preparation for the final exam.
XV week lectures	Make-up Test I and II.
XV week exercises	Make-up Test I and II.

Student workload	Per week 3 credits x 40/30 = 4 hours Structure: 2 hours of lectures 1 hours of exercises 1 hour of individual work including consultations During the semester Teaching and final exam: (4 hours) x 16 = 64 hours Necessary preparations before the semester start (administration, enrolment, verification): 2 x (4 hours and 20 minutes) = 8 hours Total hours: 3 x 30 = 90 hours Remedial classes (additional hours) for preparing the make-up exam, including the exam: 0 - 30 hours. Total workload structure: 64 hours (classes) + 8 hours (preparation) + 18 hours (remedial classes)
Per week	Per semester
3 credits x 40/30=4 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 1 excercises 1 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 4 hour(s) i 0 minuts x 16 =64 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 4 hour(s) i 0 minuts x 2 =8 hour(s) i 0 minuts Total workload for the subject: 3 x 30=90 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 18 hour(s) i 0 minuts Workload structure: 64 hour(s) i 0 minuts (cources), 8 hour(s) i 0 minuts (preparation), 18 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend classes, do homework and take the tests and exam(s).
Consultations	everyday
Literature	1. “Business Result”, David Grant, Jane Hudson and Robert McLarty, Oxford University Press. 2. “Navigate”, Intermediate B1+, Rachael Roberts, Heather Buchanan and Emma Pathare, Oxford University Press, 1. Dictionaries, Glossaries and other relevant m
Examination methods	Test I, 30 points; Test II, 30 points; Attendance: 10 points; Final exam, 30 points; Positive grade requires not less than 50 points cumulatively.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / ENGLISH LANGUAGE II

Course:

ENGLISH LANGUAGE II/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
2587	Obavezan	2	3	2+1+0

Programs	MARINE ENGINEERING
Prerequisites	There are no special requirements.
Aims	The course aims is to enable the students to successfully communicate and follow literature in English, according STCW'10 and IMO 7.02 and 7.04 ( 1.2.1.).
Learning outcomes	Upon successful completion of the course, the student will be able to: - Follow basic technical (maritime) literature in English, especially related to maritime industry, ships and crew. - Understand and communicate upon basics of maritime industry, ship’s operation, crew hierarchy, duties and responsibilities. - Successfully communicate, both orally and in writing, using technical maritime English, in accordance with the taught curriculum.
Lecturer / Teaching assistant	Zorica Đurović, MA
Methodology	Interactive classes, exercises, everyday consultation, everyday consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction to maritime industry. Major international conventions. 1.2.1
I week exercises	Introduction to maritime industry. Major international conventions. 1.2.1 Revision of grammar.
II week lectures	Ship types. Types of cargo and cargo ships. 1.2.1
II week exercises	Ship types. Types of cargo and cargo ships. 1.2.1 Grammar: comparison of adjectives.
III week lectures	Ship design and ship parts. Orientation onboard ships. 1.2.1
III week exercises	Ship design and ship parts. Orientation onboard ships. 1.2.1
IV week lectures	Crew. Engineroom crew. 1.2.1
IV week exercises	Crew. Engineroom crew. 1.2.1
V week lectures	Watchkeeping, duties and responsibilities.1.2.1
V week exercises	Watchkeeping, duties and responsibilities.1.2.1
VI week lectures	Revision and preparation for the test.
VI week exercises	Revision and preparation for the test.
VII week lectures	Test I.
VII week exercises	Test I.
VIII week lectures	Ship’s specification. Telephone communication. 1.2.1
VIII week exercises	Ship’s specification. Telephone communication. 1.2.1
IX week lectures	Crew members and communication. 1.2.1 Questions.
IX week exercises	Crew members and communication. 1.2.1
X week lectures	Engineroom, signs, parts, tools. 1.2.1
X week exercises	Engineroom, signs, parts, tools. 1.2.1 Modal verbs.
XI week lectures	Cases of emergency. Mechanical failure, electrical failure1.2.1.
XI week exercises	Cases of emergency. Mechanical failure, electrical failure1.2.1. Revision of tenses.
XII week lectures	Nationalities and flags. 1.2.1 Revision and preparation for the test.
XII week exercises	Nationalities and flags. 1.2.1 Revision and preparation for the test.
XIII week lectures	Test II.
XIII week exercises	Test II.
XIV week lectures	Revision and preparation for the final test.
XIV week exercises	Revision and preparation for the final test.
XV week lectures	Make-up Test I and II.
XV week exercises	Make-up Test I and II.

Student workload	Per week 3 credits x 40/30 = 4 hours Structure: 2 hours of lectures 1 hour of exercises 1 hour of individual work including consultations During the semester Teaching and final exam: (4 hours) x 16 = 64 hours Necessary preparations before the semester start (administration, enrolment, verification): 2 x (4 hours and 20 minutes) = 8 hours Total hours: 3 x 30 = 90 hours Remedial classes (additional hours) for preparing the make-up exam, including the exam: 0 - 30 hours. Total workload structure: 64 hours (classes) + 8 hours (preparation) + 18 hours (remedial classes)
Per week	Per semester
3 credits x 40/30=4 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 1 excercises 1 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 4 hour(s) i 0 minuts x 16 =64 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 4 hour(s) i 0 minuts x 2 =8 hour(s) i 0 minuts Total workload for the subject: 3 x 30=90 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 18 hour(s) i 0 minuts Workload structure: 64 hour(s) i 0 minuts (cources), 8 hour(s) i 0 minuts (preparation), 18 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend classes, do homework and take the tests and exam(s).
Consultations	everyday
Literature	English Language II for Marine Engineers”, compiled texts and exercises. “Maritime English”, T. Jurlina. "Engineering English and its Terminology", Lj. Bartolić. “English for maritime studies”, T.N. Blakey. Dictionaries, glossaries, grammars, instr
Examination methods	Test I: 30 points; Test II: 30 points; Final exam: 30 points; Attendance: 10 points Positive grade requires not less than 50 points cumulatively.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / ENGLISH LANGUAGE III

Course:

ENGLISH LANGUAGE III/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
2588	Obavezan	3	3	2+1+0

Programs	MARINE ENGINEERING
Prerequisites	No special requirements for the course.
Aims	Enabling the students to successfully communicate and follow literature in English, according STCW'10 and IMO 7.02 and 7.04 ( 1.2.1.).
Learning outcomes	Upon successful completion of the course, the student will be able to: - Follow and interpret basic technical literature in English, especially related to the courses taught during semester I and II. - Successfully communicate, both orally and in writing, using technical maritime English, in accordance with the taught curriculum.
Lecturer / Teaching assistant	Prof. dr Milena Dževerdanović Pejović dr Zorica Đurović
Methodology	Interactive classes and exercises, individual work, everyday consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introuduction. Revision.
I week exercises	Introduction. Revision. Comparisons.
II week lectures	Safety equipment.
II week exercises	Personal life saving appliances. Revision of grammar.
III week lectures	Survival crafts.
III week exercises	Asking questions.
IV week lectures	Fire-fighting equipment.
IV week exercises	Vocabulary exercises.
V week lectures	Diesel engine, principle of operation.
V week exercises	Passive voice, Simple Present Tense.
VI week lectures	Revision.
VI week exercises	Revision and preparation for the test.
VII week lectures	Test I.
VII week exercises	Test I.
VIII week lectures	Diesel engine classification.
VIII week exercises	Passive voice. Other tenses.
IX week lectures	Auxiliary engine.
IX week exercises	Generators. Active and passive sentences, transformations.
X week lectures	Electric motors.
X week exercises	Prepositions.
XI week lectures	Ship's electrical system.
XI week exercises	Conditionals.
XII week lectures	Tools and repairs.
XII week exercises	Conditionals.
XIII week lectures	Revision.
XIII week exercises	Preparation for the test.
XIV week lectures	Test II.
XIV week exercises	Test II.
XV week lectures	Make-up Test I or II.
XV week exercises	Make-up Test I or II.

Student workload	Per week 3 credits x 40/30 = 4 hours Structure: 2 hours of lectures 1 hours of exercises 1 hour of individual work including consultations During the semester Teaching and final exam: (4 hours) x 16 = 64 hours Necessary preparations before the semester start (administration, enrolment, verification): 2 x (4 hours and 20 minutes) = 8 hours Total hours: 3 x 30 = 90 hours Remedial classes (additional hours) for preparing the make-up exam, including the exam: 0 - 30 hours. Total workload structure: 64 hours (classes) + 8 hours (preparation) + 18 hours (remedial classes)
Per week	Per semester
3 credits x 40/30=4 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 1 excercises 1 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 4 hour(s) i 0 minuts x 16 =64 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 4 hour(s) i 0 minuts x 2 =8 hour(s) i 0 minuts Total workload for the subject: 3 x 30=90 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 18 hour(s) i 0 minuts Workload structure: 64 hour(s) i 0 minuts (cources), 8 hour(s) i 0 minuts (preparation), 18 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend the classes, take the tests and exam(s).
Consultations	everyday
Literature	“English Language III for Marine Engineers”, compiled texts and exercises. “Maritime English”, T. Jurlina. "Engineering English and its Terminology", Lj. Bartolić. “Practical Marine Electrical Knowledge", D. T. Hall. “Electrical Engineering and its Language”, D. Kovačević. “English for maritime studies”, T.N. Blakey. Dictionaries, glossaries, grammars, instruction books, publications and other relevant material.
Examination methods	Test I: 30 points; Test II: 30 points; Final exam: 30 points; Attendance: 10 points Positive grade requires not less than 50 points cumulatively.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / ENGLISH LANGUAGE IV

Course:

ENGLISH LANGUAGE IV/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
2589	Obavezan	4	3	2+1+0

Programs	MARINE ENGINEERING
Prerequisites	No prerequisites.
Aims	The subject aims to enable the students to successfully communicate in English.
Learning outcomes	Upon successful completion of this subject the student will be able to: 1. Successfully communicate both orally and in writing related to ship's systems, especially fuel, lubrication system and auxiliary machinery. 2. Be familiar with technical terminology related to the taught systems, basic tools and handling. 3. Successfully use technical English literature.
Lecturer / Teaching assistant	Prof. dr Milena Dževerdanović Pejović dr Zorica Đurović
Methodology	Interactive classes and exercises, individual work, everyday consultations

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Revision.
I week exercises	Introduction. Revision of vocabulary.
II week lectures	Auxiliary machinery. 1.2.1.
II week exercises	Pumps. 1.2.1. Relative sentences.
III week lectures	Boilers. 1.2.1.
III week exercises	Types of boilers. 1.2.1. Grammar revision.
IV week lectures	Exhaust gas boiler. 1.2.1.
IV week exercises	Active and passive sentences.
V week lectures	Fuel oils. 1.2.1.
V week exercises	Fuel types. 1.2.1. Revision of tenses.
VI week lectures	Revision.
VI week exercises	Revision and preparation for the Test I.
VII week lectures	Test I.
VII week exercises	Test I.
VIII week lectures	Fuel system. 1.2.1.
VIII week exercises	Reported Speech, Imperative.
IX week lectures	Lubrication system. 1.2.1.
IX week exercises	Reported speech, statements.
X week lectures	Cooling. 1.2.1.
X week exercises	Reported speech, questions.
XI week lectures	Circuits and components. 1.2.1.
XI week exercises	Circuits and components, voltage and resistance. Vocabulary.
XII week lectures	Letter and email writing in maritime industry.
XII week exercises	Letter and email writing in maritime industry.
XIII week lectures	Reports. Revision.
XIII week exercises	Revision and preparation for the test.
XIV week lectures	Test II.
XIV week exercises	Test II.
XV week lectures	Make-up Test I or II.
XV week exercises	Make-up Test I or II and preparation for the final exam.

Student workload
Per week	Per semester
3 credits x 40/30=4 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 1 excercises 1 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 4 hour(s) i 0 minuts x 16 =64 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 4 hour(s) i 0 minuts x 2 =8 hour(s) i 0 minuts Total workload for the subject: 3 x 30=90 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 18 hour(s) i 0 minuts Workload structure: 64 hour(s) i 0 minuts (cources), 8 hour(s) i 0 minuts (preparation), 18 hour(s) i 0 minuts (additional work)
Student obligations	The students are obliged to attend the classes, take the tests and final exam.
Consultations	Everyday before and after classes.
Literature	1. “English Language IV, Marine Engineering Department” compiled texts and exercises 2. “English Textbook for Marine Engineers”, A. Spinčić 3. “Practical Marine Electrical Knowledge”, Dennis T. Hall 4. “Maritime Correspondence”, D. Rapovac 5. “ English in
Examination methods	Test I (job interview and presentation), 30 points, Test II (written test), 30 points, Final exam (oral), 30 points, Attendance, 10 points. A positive grade requires not less than 50 points cumulatively.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE STEAM AND GAS TURBINES

Course:

MARINE STEAM AND GAS TURBINES/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
2948	Obavezan	4	5	2+1+1

Programs	MARINE ENGINEERING
Prerequisites	Exam in thermodynamics
Aims	The main objective is to study the functioning and maintenance of elements of the marine steam and gas turbine plants
Learning outcomes
Lecturer / Teaching assistant	Prof. dr Milan Šekularac, mr Draško Kovač dipl.ing.
Methodology	Lectures, exercises, projected task, consultations, field work

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Basic concepts of heat turbines
I week exercises	Numerical problems from lectures and instruction for project design
II week lectures	Basic thermodynamic analysis of thermal power plants
II week exercises	Numerical problems from lectures and instruction for project design
III week lectures	The level of efficiency and consumption of steam, heat and fuel of MST
III week exercises	Numerical problems from lectures and instruction for project design
IV week lectures	Influence of the main thermodynamic parameters on the level of efficiency of MST
IV week exercises	Numerical problems from lectures and instruction for project design
V week lectures	The principle of operation and basic scheme of work of flow part of turbines
V week exercises	Numerical problems from lectures and instruction for project design
VI week lectures	Impulse and reaction turbines
VI week exercises	Numerical problems from lectures and instruction for project design
VII week lectures	First test
VII week exercises	Reviewing the results of the first test
VIII week lectures	Marine gas turbine basic elements
VIII week exercises	Numerical problems from lectures and instruction for project design
IX week lectures	Gas turbine plants of open cycle
IX week exercises	Numerical problems from lectures and instruction for project design
X week lectures	Gas turbine plants of semi open and closed cycle
X week exercises	Numerical problems from lectures and instruction for project design
XI week lectures	The specificity of use of gas turbines
XI week exercises	Numerical problems from lectures and instruction for project design
XII week lectures	Cogeneration systems
XII week exercises	Numerical problems from lectures and instruction for project design
XIII week lectures	Basic operation of steam and gas turbines
XIII week exercises	Numerical problems from lectures and instruction for project design
XIV week lectures	Second test
XIV week exercises	Reviewing the results of the second test
XV week lectures	The correctional test. Consultation for the final exam
XV week exercises	Consultation for the final exam

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend classes and exercises, do home exercises and both tests
Consultations	Every working day from 12 to 14h
Literature	Petrović D., Brodske turbine, Fakultet za pomostvo, Kotor, 2004. Tirelli ., Brodske parne i gasne turbine, Fakultet za pomostvo, Rijeka, 2001. Brkić Lj., Parni kotlovi, Mašinski fakultet, Beograd, 2002.
Examination methods	Tests 20% each (total 40%) Two homework assignments, each to 10 % (total 20%) and are prerequisite for final exam Final exam 40% Grading Scale: 100% - 90% A; 89% - 80% B; 79% - 70% C; 69% - 60% D; 59% - 51% E; 50% - 0% F
Special remarks
Comment	Additional information can be obtained from teacher

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE AUTOMATICS

Course:

MARINE AUTOMATICS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
2959	Obavezan	5	6	3+1+1

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 3 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 3 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE AUTOMATICS

Course:

MARINE AUTOMATICS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
2959	Obavezan	5	6	3+1+1

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 3 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 3 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / INTERNET TECHNOLOGIES AND ELECTRONIC BUSINESS

Course:

INTERNET TECHNOLOGIES AND ELECTRONIC BUSINESS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
6740	Izborni	6	6	3+0+1

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 3 sat(a) theoretical classes 1 sat(a) practical classes 0 excercises 4 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE ENGINEERING DRAWINGS

Course:

MARINE ENGINEERING DRAWINGS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
8483	Obavezan	1	3	1+0+2

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
3 credits x 40/30=4 hours and 0 minuts 1 sat(a) theoretical classes 2 sat(a) practical classes 0 excercises 1 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 4 hour(s) i 0 minuts x 16 =64 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 4 hour(s) i 0 minuts x 2 =8 hour(s) i 0 minuts Total workload for the subject: 3 x 30=90 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 18 hour(s) i 0 minuts Workload structure: 64 hour(s) i 0 minuts (cources), 8 hour(s) i 0 minuts (preparation), 18 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / CONSTRUCTION AND SHIP'S STABILITY

Course:

CONSTRUCTION AND SHIP'S STABILITY/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
8484	Obavezan	3	5	2+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims	To obtain basic knowledge of ship stability and structure.
Learning outcomes	Basics of ship stability and structure.
Lecturer / Teaching assistant	Dr. Nikola Momčilović Mr. Milan Krivokapić
Methodology	Theoretical and practical (calculations) lectures. Seminar papers.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Main particulars. Tonnage.
I week exercises	Renewal of theoretical lecture and calculations.
II week lectures	Ship lines. Waterlines.
II week exercises	Renewal of theoretical lecture and calculations.
III week lectures	Hydrostatics, ship form coefficients, loading and unloading.
III week exercises	Renewal of theoretical lecture and calculations.
IV week lectures	Simpson's rules
IV week exercises	Renewal of theoretical lecture and calculations.
V week lectures	Renewal of lectures for the preparation of colloquium. Colloquium I.
V week exercises	Renewal of theoretical lecture and calculations.
VI week lectures	The basics of stability. Transversal stability. Small angles.
VI week exercises	Renewal of theoretical lecture and calculations.
VII week lectures	Transversal stability due to small angles of rolling, free surface effect.
VII week exercises	Renewal of theoretical lecture and calculations.
VIII week lectures	Transversal stability due to large angles of rolling.
VIII week exercises	Renewal of theoretical lecture and calculations.
IX week lectures	Effect of cranes and moving masses. Inclination test.
IX week exercises	Renewal of theoretical lecture and calculations.
X week lectures	Renewal of lectures for the preparation of colloquium. Colloquium II.
X week exercises	Renewal of theoretical lecture and calculations.
XI week lectures	Longitudinal stability.
XI week exercises	Renewal of theoretical lecture and calculations.
XII week lectures	Longitudinal stability due to multiple masses loading.
XII week exercises	Renewal of theoretical lecture and calculations.
XIII week lectures	Longitudinal strength
XIII week exercises	Renewal of theoretical lecture and calculations.
XIV week lectures	Basics of ship structures
XIV week exercises	Renewal of theoretical lecture and calculations.
XV week lectures	Renewal of lectures for the preparation of colloquium. Colloquium III.
XV week exercises	Renewal of theoretical lecture and calculations.

Student workload	Classes 2+2
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	To attend the classes regularly.
Consultations	Every workday.
Literature	A.Lompar Nauka o brodu, Presentations and materials provided by the lecturers. D.R. Derrett Ship Stability for Masters and Mates.
Examination methods	Theoretical and practical (calculations) past of the exam. Three colloquiums. Seminar paper.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE AUXILIARY ENGINES

Course:

MARINE AUXILIARY ENGINES/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
8965	Obavezan	3	6	3+0+1

Programs	MARINE ENGINEERING
Prerequisites	No.
Aims	Aiming to familiarize the students with auxiliary machinery and devices onboard a ship, their principles of operation and characteristics, constructive parts in accordance to STCW'10 and IMO 7.04 (1.4.1, 1.4.2, 1.4.3, 1.5.1, 1.5.2, 1.5.3).
Learning outcomes
Lecturer / Teaching assistant	Prof. dr Lazo Vujović ch. eng. - teacher Mr Draško Kovač - saradnik - assistant
Methodology	Lectures, laboratory simulator practical classes. Study and individual work on seminar papers. Consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Hydraulic power system
I week exercises
II week lectures	Pumping and piping system.
II week exercises
III week lectures	Various pumps.
III week exercises
IV week lectures	Hydraulic power rotary pumps.
IV week exercises
V week lectures	Operation of pumping systems. Routine pumping operations.
V week exercises
VI week lectures	Operation of Bilge, Ballast and Cargo Pumping Systems
VI week exercises
VII week lectures	Free Week
VII week exercises
VIII week lectures	The First Compulsory Assignment
VIII week exercises
IX week lectures	Air conditioning and ventilation systems
IX week exercises
X week lectures	Air compressor and system principles
X week exercises
XI week lectures	Fluid Flow and Characteristics of Major Systems.
XI week exercises
XII week lectures	Automatic Control Systems
XII week exercises
XIII week lectures	Power Failure (Blackout). Emergency Procedures for Other Equipment/Installations.
XIII week exercises
XIV week lectures	Preparation, operation, fault detection and necessary measures to prevent damage for the purifier and fuel oil treatment, air compressor, evaporators and distillers and refrigerator.
XIV week exercises
XV week lectures	The Second Compulsory Assignment
XV week exercises

Student workload	180 hours.
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 3 sat(a) theoretical classes 1 sat(a) practical classes 0 excercises 4 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations	Students are obliged to attend lectures, submit homework assignments and take final exam
Consultations	Every week, after lectures.
Literature	1. L. Vujović : Brodske pomoćne mašine, Univerzitet Crne Gore, (Marine Auxiliary Machinery), University of Montenegro, 2008 2.Jackson, L and Morton, T.D. General Engineering Knowledge for Marine Engineers. 5th ed. London, Thomas Reed Publications Ltd 199
Examination methods	1.First Compulsory Assignment, from 0 to 45 points; 2.The Second Compulsory Assignment, from 0 to 45 points; Seminar-homework 0-10 points 3.Final exam, from 0 to 50 (optional in the case if student failed both compulsory tests); Passing mark is awarded if the student collects 51 points
Special remarks	No.
Comment	No.

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE ELECTRIC DEVICES

Course:

MARINE ELECTRIC DEVICES/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
8969	Obavezan	4	5	2+1+1

Programs	MARINE ENGINEERING
Prerequisites	The precondition for attendance is passed exam of "Fundamentals of Electrics and Electronics"
Aims	The aim of this course is to familiarize the students with electrical system on board (electrical sources, transformers and electricity consumers), their role, application, diversity, and mathematical models. In the category of consumers, special emphasis is given to electrical machines the types and structures of which are predominantly encountered onboard ships. In addition, students are presented the application of power electronic devices that enable the conversion and adjustment of voltage and current to the devices’ operating modes.
Learning outcomes	• Explain the basic concepts in the field of marine power systems with high and low voltage (production and consumption of electric energy) • Understand the basic principles of electrical conversion • Describe AC and DC voltage sources on ships • Describe distribution of electrical energy on ships • Understand and analyze basic principle of transformer application • Distinguish different types of electric motor • Understand work principles of DC and AC induction and synchronous motor
Lecturer / Teaching assistant	Vladan RADULOVIĆ, PhD – professor
Methodology	Lectures, exercises, guiding examples, laboratory exercises. Consultation.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Electrical appliances and equipment on board. Definitions, basic division.
I week exercises
II week lectures	Sources of electrical energy on the ships. DC and AC generators.
II week exercises
III week lectures	The principle of operation of synchronous generators, design, excitation systems.
III week exercises
IV week lectures	Transformers: working principle, the basic equations, equivalent circuit of single-phase transformers.
IV week exercises
V week lectures	The power balance, parallel operation, the cooling of transformer. Three-phase transformers.
V week exercises
VI week lectures	Compulsory test I
VI week exercises	-
VII week lectures	Electricity consumers on board. Classification. Mathematical models of lighting, air conditioning, thermal consumers.
VII week exercises
VIII week lectures	Asynchronous machines: the principle of operation, torque characteristics and power losses, the utilization factor.
VIII week exercises
IX week lectures	Starters for squirrel cage induction motor, induction motor starters with wound rotor. Testing, maintenance, regulations, marine design of induction motors.
IX week exercises
X week lectures	The principle of operation of synchronous motors, staring, torque characteristics, V-curves.
X week exercises
XI week lectures	The principle of the DC motor and generator, basic equations, structure.
XI week exercises
XII week lectures	Armature reaction, types of motives, starters.
XII week exercises
XIII week lectures	Compulsory test II
XIII week exercises	-
XIV week lectures	Universal motor, maintenance, testing, regulations, ship design.
XIV week exercises
XV week lectures	Elements of marine power electronics. Rectifiers and inverters.
XV week exercises

Student workload	Per week 6 credits x 40/30 = 8 hours Structure: 3 hours of lectures 1 hour of exercises 1 hour of laboratory practice 4 hours of individual work, including consultation During semester Lectures and final exam (8 hours) x 16 = 128 hours. Necessary preparations before the start of semester (administration, enrollment, etc) 2 x (8 hours) = 16 hours. Total hours for the course 6 x 30 = 180 hours Additional hours for preparation for the correction term(s), including the exam taking from 0 to 36 hours. Structure: 128 hours (lectures) + 16 hours (preparation) + 36 hours (additional work)
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend lectures, lab work and both tests.
Consultations
Literature	1. V. Radulović, Brodski električni uređaji (Marine Electrical Devices), script 2. Dennis T. Hall „Practical Marine Electrical Knowledge“ 3. N.Bajramović, Brodski električni uređaji i postrojenja (Marine Electrical Devices and Plants), script
Examination methods	4 tests with 2.5 points (10 points) Compulsory tests I - 20 points Compulsory test II - 20 points Final exam - 50 points
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE ELECTRIC DEVICES

Course:

MARINE ELECTRIC DEVICES/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
8969	Obavezan	4	5	2+1+1

Programs	MARINE ENGINEERING
Prerequisites	The precondition for attendance is passed exam of "Fundamentals of Electrics and Electronics"
Aims	The aim of this course is to familiarize the students with electrical system on board (electrical sources, transformers and electricity consumers), their role, application, diversity, and mathematical models. In the category of consumers, special emphasis is given to electrical machines the types and structures of which are predominantly encountered onboard ships. In addition, students are presented the application of power electronic devices that enable the conversion and adjustment of voltage and current to the devices’ operating modes.
Learning outcomes	• Explain the basic concepts in the field of marine power systems with high and low voltage (production and consumption of electric energy) • Understand the basic principles of electrical conversion • Describe AC and DC voltage sources on ships • Describe distribution of electrical energy on ships • Understand and analyze basic principle of transformer application • Distinguish different types of electric motor • Understand work principles of DC and AC induction and synchronous motor
Lecturer / Teaching assistant	Vladan RADULOVIĆ, PhD – professor
Methodology	Lectures, exercises, guiding examples, laboratory exercises. Consultation.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Electrical appliances and equipment on board. Definitions, basic division.
I week exercises
II week lectures	Sources of electrical energy on the ships. DC and AC generators.
II week exercises
III week lectures	The principle of operation of synchronous generators, design, excitation systems.
III week exercises
IV week lectures	Transformers: working principle, the basic equations, equivalent circuit of single-phase transformers.
IV week exercises
V week lectures	The power balance, parallel operation, the cooling of transformer. Three-phase transformers.
V week exercises
VI week lectures	Compulsory test I
VI week exercises	-
VII week lectures	Electricity consumers on board. Classification. Mathematical models of lighting, air conditioning, thermal consumers.
VII week exercises
VIII week lectures	Asynchronous machines: the principle of operation, torque characteristics and power losses, the utilization factor.
VIII week exercises
IX week lectures	Starters for squirrel cage induction motor, induction motor starters with wound rotor. Testing, maintenance, regulations, marine design of induction motors.
IX week exercises
X week lectures	The principle of operation of synchronous motors, staring, torque characteristics, V-curves.
X week exercises
XI week lectures	The principle of the DC motor and generator, basic equations, structure.
XI week exercises
XII week lectures	Armature reaction, types of motives, starters.
XII week exercises
XIII week lectures	Compulsory test II
XIII week exercises	-
XIV week lectures	Universal motor, maintenance, testing, regulations, ship design.
XIV week exercises
XV week lectures	Elements of marine power electronics. Rectifiers and inverters.
XV week exercises

Student workload	Per week 6 credits x 40/30 = 8 hours Structure: 3 hours of lectures 1 hour of exercises 1 hour of laboratory practice 4 hours of individual work, including consultation During semester Lectures and final exam (8 hours) x 16 = 128 hours. Necessary preparations before the start of semester (administration, enrollment, etc) 2 x (8 hours) = 16 hours. Total hours for the course 6 x 30 = 180 hours Additional hours for preparation for the correction term(s), including the exam taking from 0 to 36 hours. Structure: 128 hours (lectures) + 16 hours (preparation) + 36 hours (additional work)
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend lectures, lab work and both tests.
Consultations
Literature	1. V. Radulović, Brodski električni uređaji (Marine Electrical Devices), script 2. Dennis T. Hall „Practical Marine Electrical Knowledge“ 3. N.Bajramović, Brodski električni uređaji i postrojenja (Marine Electrical Devices and Plants), script
Examination methods	4 tests with 2.5 points (10 points) Compulsory tests I - 20 points Compulsory test II - 20 points Final exam - 50 points
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE AUXILIARY MACHINERY

Course:

MARINE AUXILIARY MACHINERY/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
8970	Obavezan	4	5	3+0+1

Programs	MARINE ENGINEERING
Prerequisites	No.
Aims	Aiming to familiarize the students with auxiliary machinery and devices onboard a ship, their principles of operation and characteristics, constructive parts in accordance to STCW'10 and IMO 7.02 (1.2.5.1, 1.3.3.11-1.3.3.12, 1.3.3.14-1.3.3.15, 1.3.3.24-1.3.3.25, 1.3.5.1-1.3.5.7, 1.4.1.1-1.4.1.3).
Learning outcomes
Lecturer / Teaching assistant	Prof. dr Lazo Vujović, ch.eng. - teacher Mr Draško Kovač - assistant
Methodology	Lectures, laboratory simulator practical classes. Study and individual work on seminar papers. Consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Refrigeration and Air Conditioning system.
I week exercises
II week lectures	Refrigeration and Air Conditioning system.
II week exercises
III week lectures	Steering gear principles. Steering gear system. Steering gear electrical control.
III week exercises
IV week lectures	Hydraulic power-operated rudder systems.
IV week exercises
V week lectures	Shafting installations.
V week exercises
VI week lectures	The First Compulsory Assignment.
VI week exercises
VII week lectures	Practical lectures.
VII week exercises
VIII week lectures	Propellers.
VIII week exercises
IX week lectures	Evaporators and distillers.
IX week exercises
X week lectures	Oil purifier.
X week exercises
XI week lectures	Deck Machinery.
XI week exercises
XII week lectures	Cargo-handling equipment and deck machinery.
XII week exercises
XIII week lectures	Bilge and Ballast.
XIII week exercises
XIV week lectures	Oily water separator/similar equipment requirements and operation Prevention of Pollution of the Sea by Oil. Sewage and sludge.
XIV week exercises
XV week lectures	The Second Compulsory Assignment.
XV week exercises

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 3 sat(a) theoretical classes 1 sat(a) practical classes 0 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	90 hours.
Consultations
Literature	1. L. Vujović : Brodski uređaji i sistemi, Univerzitet Crne Gore, 2008 - (Marine Auxiliary Machinery), University of Montenegro, 2008 2.PRINCIPLES OF REFRIGERATION; ROY J. DOSSAT; PRENTICE HALL; ISBN: 978-0130272706 3.MARINE REFRIGERATION & AIR CONDITIO
Examination methods	1. First Compulsory Assignment, from 0 to 50 points; 2.The Second Compulsory Assignment, from 0 to 50 points; 3.Final exam, from 0 to 50 (optional in the case if student failed both compulsory tests); 4.Passing mark is awarded if the student collects at l
Special remarks	No.
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE ELECTRICAL SUBSTATIONS

Course:

MARINE ELECTRICAL SUBSTATIONS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
8971	Obavezan	3	4	2+1+1

Programs	MARINE ENGINEERING
Prerequisites	The precondition is passed exam of "Fundamentals of Electrics and Electronics"
Aims	The aim of this course is to introduce students to electrical substations on board and their elements (busbars, isolators, circuit breakers, disconnectors, instrument transformers), their roles, applications, divisions, choice and performance. In addition, students are introduced to the schemes of the high-voltage and low-voltage power distribution and electrical installation on board, as well as rules and recommendations for personal protection, control, management and protection of the electrical system.
Learning outcomes	• Explain the basic concepts in the field of energy distribution • Understand and distinguish voltage and current stresses on the equipment • Describe position and basic elements of electrical circuits and their symbols at schemes • Describe and analyze implementation of main switchboard and its components • Understand position, role and work principles of circuit breakers, disconnectors, instrument transformers, surge arresters and busbars. • Understand application of power electronics in modern ships • Describe and distinguish power cables.
Lecturer / Teaching assistant	Vladan RADULOVIĆ, assistant professor
Methodology	Lectures, laboratory, demonstration examples. Consultation.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Definitions and classification of marine substations. Voltage and current stresses.
I week exercises	Calculation of voltage and current stresses.
II week lectures	Elements of marine substations. Bus (the role, application, sharing, selection of cross section)
II week exercises	Calculation of bus cross section.
III week lectures	Insulators (role, application, divisions, selection)
III week exercises	Selection of insulators
IV week lectures	Circuit breakers (role, application, divisions, selection). Fuses.
IV week exercises	Calculation and selection of circuit breakers and fuses
V week lectures	Disconnectors (role, application, sharing, selection). Power disconnectors.
V week exercises	Calculation of disconnectors
VI week lectures	Compulsory test I
VI week exercises	-
VII week lectures	Instrument current transformers.
VII week exercises	Calculation and selection of instrument current transformers.
VIII week lectures	Instrument voltage transformers.
VIII week exercises	Calculation and selection of instrument voltage transformers.
IX week lectures	Schemes of high-voltage power distribution in the ship's electrical systems.
IX week exercises	Application of schemes
X week lectures	The layout of elements in marine substations. SF6 and vacuum insulated shielded facilities.
X week exercises	Determination of layout.
XI week lectures	Low voltage electrical installations on board.
XI week exercises	Selection of conductors in low-voltage power installations.
XII week lectures	The cables on ships. Division, equivalent schemes. Load of cables.
XII week exercises	Selection of cables
XIII week lectures	Compulsory test II
XIII week exercises	-
XIV week lectures	Auxiliary power circuit and system protection.
XIV week exercises	Determination of auxiliary power circuits
XV week lectures	Protection by earthing and protection against electric shock.
XV week exercises	Calculation of earthing.

Student workload	Per week 5 credits x 40/30 = 6 hours and 40 minutes Structure: 3 hours of lectures 2 hours of laboratory exercises 1 hour and 40 minutes if individual work, including consultation During semester Lectures and final exam (6 hours and 40 min.) X 16 = 106 hours and 40 min. Necessary preparations before the start of semester (administration, enrollment, etc) 2 x (6 hours and 40 min.) = 13 hours and 20 min. Total hours for the course 5 x 30 = 150 hours Additional hours for the preparation of the correction term(s), including exam taking, 0 to 30 hours. Structure: 106 hours and 40 min. (Lectures) + 13 hours and 20 min. (Preparation) + 30 hours (additional work)
Per week	Per semester
4 credits x 40/30=5 hours and 20 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 1 hour(s) i 20 minuts of independent work, including consultations	Classes and final exam: 5 hour(s) i 20 minuts x 16 =85 hour(s) i 20 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 5 hour(s) i 20 minuts x 2 =10 hour(s) i 40 minuts Total workload for the subject: 4 x 30=120 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 24 hour(s) i 0 minuts Workload structure: 85 hour(s) i 20 minuts (cources), 10 hour(s) i 40 minuts (preparation), 24 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend classes and to both tests.
Consultations
Literature	1. V. Radulović, Brodska električna postrojenja, skripta u izradi 2. Dennis T. Hall „Practical Marine Electrical Knowledge“ 3. N.Bajramović, Brodski električni uređaji i postrojenja, skripta
Examination methods	4 tests x 2.5 points (10 points) Compulsory test I - 20 points Compulsory test II - 20 points Final exam - 50 points
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE ELECTRICAL SUBSTATIONS

Course:

MARINE ELECTRICAL SUBSTATIONS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
8971	Obavezan	3	4	2+1+1

Programs	MARINE ENGINEERING
Prerequisites	The precondition is passed exam of "Fundamentals of Electrics and Electronics"
Aims	The aim of this course is to introduce students to electrical substations on board and their elements (busbars, isolators, circuit breakers, disconnectors, instrument transformers), their roles, applications, divisions, choice and performance. In addition, students are introduced to the schemes of the high-voltage and low-voltage power distribution and electrical installation on board, as well as rules and recommendations for personal protection, control, management and protection of the electrical system.
Learning outcomes	• Explain the basic concepts in the field of energy distribution • Understand and distinguish voltage and current stresses on the equipment • Describe position and basic elements of electrical circuits and their symbols at schemes • Describe and analyze implementation of main switchboard and its components • Understand position, role and work principles of circuit breakers, disconnectors, instrument transformers, surge arresters and busbars. • Understand application of power electronics in modern ships • Describe and distinguish power cables.
Lecturer / Teaching assistant	Vladan RADULOVIĆ, assistant professor
Methodology	Lectures, laboratory, demonstration examples. Consultation.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Definitions and classification of marine substations. Voltage and current stresses.
I week exercises	Calculation of voltage and current stresses.
II week lectures	Elements of marine substations. Bus (the role, application, sharing, selection of cross section)
II week exercises	Calculation of bus cross section.
III week lectures	Insulators (role, application, divisions, selection)
III week exercises	Selection of insulators
IV week lectures	Circuit breakers (role, application, divisions, selection). Fuses.
IV week exercises	Calculation and selection of circuit breakers and fuses
V week lectures	Disconnectors (role, application, sharing, selection). Power disconnectors.
V week exercises	Calculation of disconnectors
VI week lectures	Compulsory test I
VI week exercises	-
VII week lectures	Instrument current transformers.
VII week exercises	Calculation and selection of instrument current transformers.
VIII week lectures	Instrument voltage transformers.
VIII week exercises	Calculation and selection of instrument voltage transformers.
IX week lectures	Schemes of high-voltage power distribution in the ship's electrical systems.
IX week exercises	Application of schemes
X week lectures	The layout of elements in marine substations. SF6 and vacuum insulated shielded facilities.
X week exercises	Determination of layout.
XI week lectures	Low voltage electrical installations on board.
XI week exercises	Selection of conductors in low-voltage power installations.
XII week lectures	The cables on ships. Division, equivalent schemes. Load of cables.
XII week exercises	Selection of cables
XIII week lectures	Compulsory test II
XIII week exercises	-
XIV week lectures	Auxiliary power circuit and system protection.
XIV week exercises	Determination of auxiliary power circuits
XV week lectures	Protection by earthing and protection against electric shock.
XV week exercises	Calculation of earthing.

Student workload	Per week 5 credits x 40/30 = 6 hours and 40 minutes Structure: 3 hours of lectures 2 hours of laboratory exercises 1 hour and 40 minutes if individual work, including consultation During semester Lectures and final exam (6 hours and 40 min.) X 16 = 106 hours and 40 min. Necessary preparations before the start of semester (administration, enrollment, etc) 2 x (6 hours and 40 min.) = 13 hours and 20 min. Total hours for the course 5 x 30 = 150 hours Additional hours for the preparation of the correction term(s), including exam taking, 0 to 30 hours. Structure: 106 hours and 40 min. (Lectures) + 13 hours and 20 min. (Preparation) + 30 hours (additional work)
Per week	Per semester
4 credits x 40/30=5 hours and 20 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 1 hour(s) i 20 minuts of independent work, including consultations	Classes and final exam: 5 hour(s) i 20 minuts x 16 =85 hour(s) i 20 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 5 hour(s) i 20 minuts x 2 =10 hour(s) i 40 minuts Total workload for the subject: 4 x 30=120 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 24 hour(s) i 0 minuts Workload structure: 85 hour(s) i 20 minuts (cources), 10 hour(s) i 40 minuts (preparation), 24 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend classes and to both tests.
Consultations
Literature	1. V. Radulović, Brodska električna postrojenja, skripta u izradi 2. Dennis T. Hall „Practical Marine Electrical Knowledge“ 3. N.Bajramović, Brodski električni uređaji i postrojenja, skripta
Examination methods	4 tests x 2.5 points (10 points) Compulsory test I - 20 points Compulsory test II - 20 points Final exam - 50 points
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / PREPARATION AND POWER PLANT MANAGEMENT

Course:

PREPARATION AND POWER PLANT MANAGEMENT/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
8972	Obavezan	5	5	2+0+1

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 0 excercises 3 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / SHIP TRANSPORTING FACILITIES

Course:

SHIP TRANSPORTING FACILITIES/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
9228	Obavezan	6	6	2+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 4 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / PHYSICAL EDUCATION I

Course:

PHYSICAL EDUCATION I/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
9887	Obavezan	4	3	1+0+2

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
3 credits x 40/30=4 hours and 0 minuts 1 sat(a) theoretical classes 2 sat(a) practical classes 0 excercises 1 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 4 hour(s) i 0 minuts x 16 =64 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 4 hour(s) i 0 minuts x 2 =8 hour(s) i 0 minuts Total workload for the subject: 3 x 30=90 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 18 hour(s) i 0 minuts Workload structure: 64 hour(s) i 0 minuts (cources), 8 hour(s) i 0 minuts (preparation), 18 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / TECHNOLOGY OF MATERIALS

Course:

TECHNOLOGY OF MATERIALS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
10238	Obavezan	1	4	2+1+1

Programs	MARINE ENGINEERING
Prerequisites	There are no special requirements.
Aims	Through this course, students gain theoretical and practical basis of the current technologies and materials in accordance with the requirements STCW10 Convention (Table A-III/1 and A-III/2) and IMO model course 7.04 (para 3.1) and model course 7.02 (para 1.2.7).
Learning outcomes	Distinguish between material properties. - Perform independent testing of material properties and interpret them. - Select the methods of heat treatment of materials, depending on the required characteristics. - Identify the causes of corrosion and material adequate protection against corrosive effects. - Describe the basics of welding technology. - Distinguish procedures and welding parameters depending on the welding materials. - Define the elements of cutting technology
Lecturer / Teaching assistant	Full Professor Mileta Janjić, PhD; Marko Mumović, MSc
Methodology	Lectures, computer exercises, project assignments, homework assignments, consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Engineering materials in shipbuilding. The choice of materials. Basic metalurgy of metals. (IMO 7.04; 3.1.1.1) (IMO 7.04; 3.2.5.1-3.2.5.2)
I week exercises	Introduction to material testing. Tests with sample destruction, tests without sample destruction. Tensile testing of materials.
II week lectures	The structure of the material. Stresses and deformations. Desstructive and non-destructive testing of materials. (IMO 7.04; 3.1.1.2), (IMO 7.02; 1.2.7).
II week exercises	Laboratory exercise Tensile test, determination of displacement force diagram, stress, unit elongation, percentage elongation and contraction of the test specimen.
III week lectures	Metallic materials. Testing of mechanical properties. (IMO 7.04; 3.1.3.2) (IMO 7.04; 3.2.5.3).
III week exercises	Material testing by compression.
IV week lectures	Non-Metallic materialls. Corrosion of metals. (IMO 7.04; 3.1.1.3).
IV week exercises	Laboratory exercise Compression test. Determination of compressive strength, actual compressive strength, percentage shortening and percentage expansion.
V week lectures	Heat processing of the material. Thermochemical treatment. (IMO 7.04; 3.1.2.1, 3.1.2.2).
V week exercises	Testing the hardness of the material. Overview of methods, static force testing according to Brinell, Meyer, Vickers and Rockwell methods.
VI week lectures	Technological test. (IMO 7.04; 3.1.3.1, 3.1.3.3, 3.1.3.4, 3.1.3.7, 3.1.7)
VI week exercises	Laboratory exercise testing the hardness of metal materials according to the Vickers method.
VII week lectures	Test I
VII week exercises	Colloquium I
VIII week lectures	Basic of scraping. Tools. (IMO 7.04; 3.1.6.1, 3.1.6.2, 3.1.6.4).
VIII week exercises	Hardness testing by dynamic force action.
IX week lectures	Elements of scraping proces. (IMO 7.04; 3.1.5).
IX week exercises	Testing the impact toughness of materials according to the Charpy and Izod methods.
X week lectures	Workability. Machines. (IMO 7.04; 3.1.6.3.-1,2,3)
X week exercises	Laboratory exercise on machine tools. Universal lathe, universal milling machine, column drill.
XI week lectures	Basics of welding process. Definition of terms. Classification and properties of welded joints. (IMO 7.04; 3.1.6.3 - 4 f,h)
XI week exercises	Laboratory exercise on CNC machines. CNC lathe, CNC milling machine, Machining center.
XII week lectures	Oxyfuel gas. Arc welding. Submerged arc welding.( IMO 7.04; 3.1.6.3 - 4 a,b)
XII week exercises	Application of welding procedures according to material and series criteria.
XIII week lectures	Welding in protective gas. Welding electrical resistance. Other welding processes. (IMO 7.04; 3.1.6.3 - 4 c,d)
XIII week exercises	Laboratory exercise in welding. MMAW and MIG/MAG, TIG and FSW procedures.
XIV week lectures	Thermal cutting. Soldering and Bonding. (IMO 7.04; 3.1.3.5, 3.1.3.6, 3.1.4, 3.1.6.3 - 4 e,g).
XIV week exercises	Defense of reports from practical exercises.
XV week lectures	Test II
XV week exercises	Colloquium II

Student workload	Teaching and final exam: (5hours and 20 minutes) x 16 = 85 hours and 20 minutes Necessary preparations before the semester start (administration, enrolment, verification): 2 x (5 hours and 20 minutes) = 10 hours and 40 minutes Total hours: 4 x 30 = 120 hours Remedial classes (additional hours) for preparing the make-up exam, including the exam (0 to 30). Total workload structure: 85 hours and 20 minutes (lectures) + 10 hours and 40 minutes (preparation) + 24 hours (remedial classes)
Per week	Per semester
4 credits x 40/30=5 hours and 20 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 1 hour(s) i 20 minuts of independent work, including consultations	Classes and final exam: 5 hour(s) i 20 minuts x 16 =85 hour(s) i 20 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 5 hour(s) i 20 minuts x 2 =10 hour(s) i 40 minuts Total workload for the subject: 4 x 30=120 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 24 hour(s) i 0 minuts Workload structure: 85 hour(s) i 20 minuts (cources), 10 hour(s) i 40 minuts (preparation), 24 hour(s) i 0 minuts (additional work)
Student obligations	Lectures, auditory exercises, laboratory exercises, reports from laboratory exercises, consultations
Consultations
Literature	. Vukčević M.M., Tehnologija materijala I-II, Pomorski fakultet, Kotor, 2017. 2. Vukčević M. M., Šibalić N., Tehnologija mašinske obrade, Mašinski fakultet, Podgorica, 2017.
Examination methods	General activity in teaching 5 points Practical exercises up to 15 points. Test I, up to 20 points. Test II, up to 20 points. Final exam, up to 40 points. Positive mark requires not less than 50 points cumulatively.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / BASICS OF MARINE ELECTROTECHN. AND ELECTRONICS II

Course:

BASICS OF MARINE ELECTROTECHN. AND ELECTRONICS II/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
10239	Obavezan	2	5	2+1+1

Programs	MARINE ENGINEERING
Prerequisites	There are no special requirements.
Aims	To familiarize students with basic laws and principles in electrical engineering and electronics necessary for more further study levels, considering STCW10 convention (Tables A-III/1 and A-III/2) and IMO model courses 7.04 (paragraphs 2.1.1.1.1, 2.1.1.1.9, 2.1.1.1.10, (2.1.1.1.2) , 2.1.2.2.1, 2.1.2.2.2, 2.2.2.2.4, 2.2.2.2.6) and 7.02 (2.1.1.1.1)
Learning outcomes	Upon successful completion of this subject the student will be able to: - Define and apply all laws on alternating (mono-phase and three-phase) electrical and electric circuits, - Define and apply the principles of operations of transistors (BJT, FET, MOSFET, IGBT) as well as their relevant circuits - Analyse and calculate complex circuits of alternating current, as well as electronic diodes circuits, transistors and amplifiers, - Plan and perform measurements on alternating current circuits and electronic diodes circuits, transistors and amplifiers, - Be familiar with all relevant precautions for working with alternating current
Lecturer / Teaching assistant	Assistant Professor Tatijana Dlabač, PhD; Teaching assistant Ivana Čavor
Methodology	Lectures, exercises, laboratory exercises, homeworks, tests and final exam. Individual work. Consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Magnetic field. Electromagnetic force. Electromagnetic induction.7.04 (2.1.1.1.2 (2)), 7.04 (2.1.1.1.3.(1)))
I week exercises
II week lectures	Magnetic flux. States Faradays law. States Lenzs law. Self and mutual induction. 7.04 (2.1.1.1.2 (2))
II week exercises
III week lectures	Magnetic materials. Magnetic circuit. Transformers - working principles. 7.04 (2.1.1.1.4(3))
III week exercises
IV week lectures	Magnetic circuit energy. Solving magnetic circuit.
IV week exercises
V week lectures	Alternating circuit – Introduction. Differences between AC and DC. R.m.s. and mean value of alternate current and voltages. Craft vector, phasors diagram. Power in alternating circuit. Power factor. Measurements. 7.04 (2.1.1.1.2 (1)), 7.04 (2.2.2.2.4)
V week exercises
VI week lectures	Test I
VI week exercises
VII week lectures	Analysis of the basic elements of R, L and C. Impedance. 7.04 (2.1.1.1.2 (1)), 7.02 ( 2.2.1.1.3)
VII week exercises
VIII week lectures	Analysis of RL and RC circuits. Vector diagram. Phasors.7.04 (2.1.1.1.2 (1))
VIII week exercises
IX week lectures	RLC circuit and resonance. Complex analysis method.
IX week exercises
X week lectures	The system of three-phase alternating current. Three phase power. 7.04 (2.1.1.1.2 (1))
X week exercises
XI week lectures	Measurement of AC current . Measuring of electric power. 7.02 ( 2.2.1.1.3)
XI week exercises
XII week lectures	RL, RC and RLC circuits in transient states.
XII week exercises
XIII week lectures	Test II
XIII week exercises
XIV week lectures	Transistors, thyristors, amplifiers circuits.7.04 (2.1.2.2.2), 7.02 ( 2.1.1.1.2)
XIV week exercises
XV week lectures	Filters, voltage stabilizers, amplifiers, integral circuits. 7.04 (2.1.2.2.2), 7.02 ( 2.1.1.1.2)
XV week exercises

Student workload	Per week 5 credits x 40/30 =6 hours and 40 minutes Structure: 2 hours of lectures 1 hours of exercises 1 hours of practical exercises 2 hour and 40 minutes of individual work including consultations During the semester Teaching and final exam: (6 hours and 40 minutes) x 16 = 106 hours and 40 minutes Necessary preparations before the semester start (administration, enrolment, verification): 2 x (6 hours and 40 minutes) = 13 hours and 20 minutes Total hours: 5 x 30 = 150 hours Remedial classes (additional hours) for preparing the make-up exam, including the exam (0 to 30). Total workload structure: 106 hours and 40 minutes (lectures) + 13 hours and 20 minutes (preparation) + 30 hours (remedial classes)
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend classes, do homework and both tests.
Consultations
Literature	Books: 1. Lister Eugene, Rusch Robert, Electric circuitsandmachines, McGraw, ISBN:9780028018096. 2. REEDs Volume 7: Advanced electrotechnology for engineers. 2nd Ed., KRAAL, E.G. I London, Adlard Coles Nautical, 2008. LITERATURE: 1. G. Joksimović: F
Examination methods	1. Test I, up to 15 points; 2. Test II, up to 20 points; 3.Homework and tests, up to 8 points; Laboratory exercises 0 - 22 points; 5. Final exam, 0 - 35 points; Positive mark requires not less than 50 points cumulatively.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / BASICS OF MARINE ELECTROTECHN. AND ELECTRONICS II

Course:

BASICS OF MARINE ELECTROTECHN. AND ELECTRONICS II/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
10239	Obavezan	2	5	2+1+1

Programs	MARINE ENGINEERING
Prerequisites	There are no special requirements.
Aims	To familiarize students with basic laws and principles in electrical engineering and electronics necessary for more further study levels, considering STCW10 convention (Tables A-III/1 and A-III/2) and IMO model courses 7.04 (paragraphs 2.1.1.1.1, 2.1.1.1.9, 2.1.1.1.10, (2.1.1.1.2) , 2.1.2.2.1, 2.1.2.2.2, 2.2.2.2.4, 2.2.2.2.6) and 7.02 (2.1.1.1.1)
Learning outcomes	Upon successful completion of this subject the student will be able to: - Define and apply all laws on alternating (mono-phase and three-phase) electrical and electric circuits, - Define and apply the principles of operations of transistors (BJT, FET, MOSFET, IGBT) as well as their relevant circuits - Analyse and calculate complex circuits of alternating current, as well as electronic diodes circuits, transistors and amplifiers, - Plan and perform measurements on alternating current circuits and electronic diodes circuits, transistors and amplifiers, - Be familiar with all relevant precautions for working with alternating current
Lecturer / Teaching assistant	Assistant Professor Tatijana Dlabač, PhD; Teaching assistant Ivana Čavor
Methodology	Lectures, exercises, laboratory exercises, homeworks, tests and final exam. Individual work. Consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Magnetic field. Electromagnetic force. Electromagnetic induction.7.04 (2.1.1.1.2 (2)), 7.04 (2.1.1.1.3.(1)))
I week exercises
II week lectures	Magnetic flux. States Faradays law. States Lenzs law. Self and mutual induction. 7.04 (2.1.1.1.2 (2))
II week exercises
III week lectures	Magnetic materials. Magnetic circuit. Transformers - working principles. 7.04 (2.1.1.1.4(3))
III week exercises
IV week lectures	Magnetic circuit energy. Solving magnetic circuit.
IV week exercises
V week lectures	Alternating circuit – Introduction. Differences between AC and DC. R.m.s. and mean value of alternate current and voltages. Craft vector, phasors diagram. Power in alternating circuit. Power factor. Measurements. 7.04 (2.1.1.1.2 (1)), 7.04 (2.2.2.2.4)
V week exercises
VI week lectures	Test I
VI week exercises
VII week lectures	Analysis of the basic elements of R, L and C. Impedance. 7.04 (2.1.1.1.2 (1)), 7.02 ( 2.2.1.1.3)
VII week exercises
VIII week lectures	Analysis of RL and RC circuits. Vector diagram. Phasors.7.04 (2.1.1.1.2 (1))
VIII week exercises
IX week lectures	RLC circuit and resonance. Complex analysis method.
IX week exercises
X week lectures	The system of three-phase alternating current. Three phase power. 7.04 (2.1.1.1.2 (1))
X week exercises
XI week lectures	Measurement of AC current . Measuring of electric power. 7.02 ( 2.2.1.1.3)
XI week exercises
XII week lectures	RL, RC and RLC circuits in transient states.
XII week exercises
XIII week lectures	Test II
XIII week exercises
XIV week lectures	Transistors, thyristors, amplifiers circuits.7.04 (2.1.2.2.2), 7.02 ( 2.1.1.1.2)
XIV week exercises
XV week lectures	Filters, voltage stabilizers, amplifiers, integral circuits. 7.04 (2.1.2.2.2), 7.02 ( 2.1.1.1.2)
XV week exercises

Student workload	Per week 5 credits x 40/30 =6 hours and 40 minutes Structure: 2 hours of lectures 1 hours of exercises 1 hours of practical exercises 2 hour and 40 minutes of individual work including consultations During the semester Teaching and final exam: (6 hours and 40 minutes) x 16 = 106 hours and 40 minutes Necessary preparations before the semester start (administration, enrolment, verification): 2 x (6 hours and 40 minutes) = 13 hours and 20 minutes Total hours: 5 x 30 = 150 hours Remedial classes (additional hours) for preparing the make-up exam, including the exam (0 to 30). Total workload structure: 106 hours and 40 minutes (lectures) + 13 hours and 20 minutes (preparation) + 30 hours (remedial classes)
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend classes, do homework and both tests.
Consultations
Literature	Books: 1. Lister Eugene, Rusch Robert, Electric circuitsandmachines, McGraw, ISBN:9780028018096. 2. REEDs Volume 7: Advanced electrotechnology for engineers. 2nd Ed., KRAAL, E.G. I London, Adlard Coles Nautical, 2008. LITERATURE: 1. G. Joksimović: F
Examination methods	1. Test I, up to 15 points; 2. Test II, up to 20 points; 3.Homework and tests, up to 8 points; Laboratory exercises 0 - 22 points; 5. Final exam, 0 - 35 points; Positive mark requires not less than 50 points cumulatively.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / SHIP KNOWLEDGE

Course:

SHIP KNOWLEDGE/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
10240	Obavezan	2	5	2+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims	To obtain knowledge on ship and ship's parameters. Geometry, form, stability and structure.
Learning outcomes	Knowledge on ship and ship's parameters. Geometry, form, stability and structure.
Lecturer / Teaching assistant	Dr. Nikola Momčilović Mr. Milan Krivokapić
Methodology	Theoretical and practical (calculations) lectures.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Main particulars. Form. Parameters.
I week exercises	Theoretical lecture renewal and production of calculations.
II week lectures	Coefficients of ship form. Simpson's rule.
II week exercises	Theoretical lecture renewal and production of calculations.
III week lectures	Hydrostatics, parameters dependence on draught. Loading and unlaoding of ships.
III week exercises	Theoretical lecture renewal and production of calculations.
IV week lectures	Ship theory. The basics of floating bodies.
IV week exercises	Theoretical lecture renewal and production of calculations.
V week lectures	The basics of ship stability. Still water conditions. Small angles.
V week exercises	Theoretical lecture renewal and production of calculations.
VI week lectures	Loading conditions and their impact on stability. Mass movement, cranes, wind effect.
VI week exercises	Theoretical lecture renewal and production of calculations.
VII week lectures	Loading conditions and their impact on stability - continued. Criteria, regulations, IMO.
VII week exercises	Theoretical lecture renewal and production of calculations.
VIII week lectures	Inclination test, theory.
VIII week exercises	Theoretical lecture renewal and production of calculations.
IX week lectures	More detail analysis on stability (free surface effect).
IX week exercises	Theoretical lecture renewal and production of calculations.
X week lectures	Renewal of lectures. Colloquium I.
X week exercises	Theoretical lecture renewal and production of calculations.
XI week lectures	Basics of longitudinal stability, trim.
XI week exercises	Theoretical lecture renewal and production of calculations.
XII week lectures	Loading condition involving longitudinal movement of mass.
XII week exercises	Theoretical lecture renewal and production of calculations.
XIII week lectures	Basics of ship structures.
XIII week exercises	Theoretical lecture renewal and production of calculations.
XIV week lectures	Longitudinal strength.
XIV week exercises	Theoretical lecture renewal and production of calculations.
XV week lectures	Ship resistance and propulsion. Ship equipment, ship systems.
XV week exercises	Theoretical lecture renewal and production of calculations.

Student workload	Classes 2+2
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations	To regularly attend the classes. Seminar paper production.
Consultations	Every workday.
Literature	Presentations and materials given by the lecturers. Dokkum: Ship Knowledge. A. Lompar: Nauka o brodu, D.R. Derrett: Ship Stability for Masters and Mates.
Examination methods	Colloquiums. Semina papers.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / THERMODYNAMICS AND HEAT TRANSFER

Course:

THERMODYNAMICS AND HEAT TRANSFER/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
10241	Obavezan	2	6	3+2+0

Programs	MARINE ENGINEERING
Prerequisites	No.
Aims	Introduction with the basic concept and terms of thermodynamics, the specifics of thermal energy and its utilization for obtaining work
Learning outcomes	After passing the exam, the student is expected to: 1. Understands and knows how to describe basic thermodynamic terms and quantities 2. Correctly interprets thermal energy as a term 3. Correctly interprets Thermodynamic System as a term 4. Understands the exchange of energy between parts of the system 5. Understands heat transfer mechanisms 6. Understands the essence of steam and real gases 7. Understands the concept of ideal gases 8. Able to describe thermodynamic processes 9. Able to describe and understand the transformation of heat into work and vice versa
Lecturer / Teaching assistant	Prof. dr Igor Vušanović, Mr Draško Kovač
Methodology	Auditory lectures, exercises, preparation of seminar papers, colloquium

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Basics of thermodynamics. State sizes. Thermodynamic system. Heat and work. Specific heat. Basics of molecular kinetic theory of gases.
I week exercises
II week lectures	Ideal gas. Equation of state.
II week exercises
III week lectures	Real gases and vapor. Phase diagram. Energy work and heat in real gases.
III week exercises
IV week lectures	First and Second law of thermodynamics. Display in p - v and T - s coordinate system. Stationary and non-stationary processes. Reversible and irreversible processes. Changes of state. A mixture of gases
IV week exercises
V week lectures	Right-handed and left-handed cycles. Carnot cycle, cycles of heat engines and gas turbines. Coefficient of thermodynamic efficiency.
V week exercises
VI week lectures	Colloquium I
VI week exercises
VII week lectures	Cycles with real gases. Rankin Claussius cycle.
VII week exercises
VIII week lectures	I Law of thermodynamics for an open system.
VIII week exercises
IX week lectures	Flow of gases. The speed of sound. Nozzles.
IX week exercises
X week lectures	Colloquium II
X week exercises
XI week lectures	Elements of Heat transfer. The main transport mechanisms: convection, conduction, ventilation.
XI week exercises
XII week lectures	Combined convection-conduction heat transfer. Heat exchangers.
XII week exercises
XIII week lectures	Humid air.
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload	In the semester Lessons and final exam: 8 hours x 16 = 128 hours Necessary preparations before the beginning of the semester (administration, registration, certification) 8 hours x 2 = 16 hours Total load for the course: 6 x 30 = 180 hours For exam preparation in the make-up exam period, including taking the make-up exam: 180 - (144 hours) = 36 hours Load structure: 128 hours (teaching) + 16 hours (preparation) + 36 hours (additional work)
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 3 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 3 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations	Students are obliged to attend classes, do homework and take the final exam
Consultations	Every weekday from 12 - 2PM
Literature	LITERATURE: 1. N. Kažić, Thermodynamics - authorized lectures, Manual for Thermodynamics - Kotor, 2006. 2. D. Malić, Thermodynamics and thermotechnics, Scientific book, Belgrade, 1988. 3. Djordjević, Vasiljević, Bekavac, Collection of problems from thermodynamics, MF, Belgrade, 2000.
Examination methods	FORMS OF KNOWLEDGE CHECK AND ASSESSMENT: 1. Colloquium I, from 0 to 25 points; 2. Colloquium II, from 0 to 25 points; 3. Final exam, from 0 to 50 points; A student has passed the exam if he/she collects at least 51 points during the semester.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / BASICS OF MARINE ELECTROTECHN. AND ELECTRONICS I

Course:

BASICS OF MARINE ELECTROTECHN. AND ELECTRONICS I/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
10242	Obavezan	1	5	2+1+1

Programs	MARINE ENGINEERING
Prerequisites	There are no special requirements.
Aims	To familiarize students with basic laws and principles in electrical engineering and electronics necessary for more further study levels, considering STCW10 convention (Tables A-III/1 and A-III/2) and IMO model courses 7.04 (paragraphs 2.1.1.1.1, 2.1.1.1.9, 2.1.1.1.10, (2.1.1.1.2) , 2.1.2.2.1, 2.1.2.2.2, 2.2.2.2.4, 2.2.2.2.6) and 7.02 (2.1.1.1.1)
Learning outcomes	Upon successful completion of this subject the student will be able to: - Define and apply all the laws on direct, electrostatic and magnetic circuits; - Define and apply principles of operation of p-n connections and diodes, as well as electronic diodes circuits - Analyze and calculate complex electrostatic and electrical circuits of direct current and electronic diodes circuits; - Plan and perform measurements on electrical circuits of direct current and diodes circuits; - Be familiar with all relevant precautions for working with direct current.
Lecturer / Teaching assistant	Associate professor Tatijana Dlabač, PhD; Teaching assistant Ivana Čavor
Methodology	Lectures, exercises, laboratory exercises, homeworks, tests and final exam. Individual work. Consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Electricity. Coulombs law. The electric field vector. Potential. Voltage. 7.04 (2.2.2.2.6)
I week exercises
II week lectures	Conductors in electrostatic field. Capacitance. Capacitors. Connecting of capacitor.
II week exercises
III week lectures	Dielectrics. Class of isolation. Dielectrics in the electrostatic field. Electrostatic field energy.
III week exercises
IV week lectures	Direct current. Electrical resistance. Cables. Basic measurements in electrical circuit. 7.04 (2.1.1.1.1 (1)), 7.04 (2.1.1.1 (3)), (2.1.1.1.9), 7.02 (2.1.1.1.1)
IV week exercises
V week lectures	Ohms Law. Joules law. Simple electrical circuits. 7.04 (2.1.1.1.1 (1)), 7.04 (2.1.1.1.1(3)), 7.02 (2.1.1.1.1 )
V week exercises
VI week lectures	Basic measurements in electrical circuit (measurement of the DC voltage and current). Analog and digital instruments for voltage and currents measurement. 7.04 (2.2.2.2.4), 7.04 (2.1.1.1.2 (3))
VI week exercises
VII week lectures	Test I
VII week exercises
VIII week lectures	Kirchhoff laws. Complex circuits. Connecting of resistor. 7.04 (2.1.1.1.1(2))
VIII week exercises
IX week lectures	IX week Sources of electricity. Connecting of sources. Accumulators. Batteries. 7.04 (2.1.1.1.10)
IX week exercises
X week lectures	States Kirchhoff’s laws and uses the laws in solving complex electrical circuits. 7.04 (2.1.1.1.1 (2))
X week exercises
XI week lectures	Node-voltage analysis. Mesh-current analysis.
XI week exercises
XII week lectures	Fundamentals of semiconductor physics. Semiconductors of type P and N. 7.04 (2.1.2.2.1)
XII week exercises
XIII week lectures	Test II
XIII week exercises
XIV week lectures	P -N connections. Diodes. 7.04 (2.1.2.2.2 (1))
XIV week exercises
XV week lectures	Diodes circuit. 7.04 (2.1.2.2.2 (1))
XV week exercises

Student workload	5 credits x 40/30 = 6 hours and 40 minutes Structure: 2 hours of lectures 1 hours of exercises 1 hours of practical exercises 2 hour and 40 minutes of individual work including consultations
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature	1. G. Joksimović: Fundamentals of Electrical Engineering I, Fundamentals of Electrical Engineering II, books (in Montenegrin), 2007. 2. D. Filipović, T. Vučković: Fundamentals of Electrical Engineering, book (in Montenegrin), 1997. 3. D. Filipović, T. V
Examination methods	Two tests up to 10 points during the semester, from 0 to 15 points (up to 30 points in total); Laboratory exercises, from 0 to 10 points; Homework and tests, from 0 to 10 points; Final exam, from 0 to 50 points (10 points practical work); A passing grade is obtained if at least 50 points are collected.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / BASICS OF MARINE ELECTROTECHN. AND ELECTRONICS I

Course:

BASICS OF MARINE ELECTROTECHN. AND ELECTRONICS I/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
10242	Obavezan	1	5	2+1+1

Programs	MARINE ENGINEERING
Prerequisites	There are no special requirements.
Aims	To familiarize students with basic laws and principles in electrical engineering and electronics necessary for more further study levels, considering STCW10 convention (Tables A-III/1 and A-III/2) and IMO model courses 7.04 (paragraphs 2.1.1.1.1, 2.1.1.1.9, 2.1.1.1.10, (2.1.1.1.2) , 2.1.2.2.1, 2.1.2.2.2, 2.2.2.2.4, 2.2.2.2.6) and 7.02 (2.1.1.1.1)
Learning outcomes	Upon successful completion of this subject the student will be able to: - Define and apply all the laws on direct, electrostatic and magnetic circuits; - Define and apply principles of operation of p-n connections and diodes, as well as electronic diodes circuits - Analyze and calculate complex electrostatic and electrical circuits of direct current and electronic diodes circuits; - Plan and perform measurements on electrical circuits of direct current and diodes circuits; - Be familiar with all relevant precautions for working with direct current.
Lecturer / Teaching assistant	Associate professor Tatijana Dlabač, PhD; Teaching assistant Ivana Čavor
Methodology	Lectures, exercises, laboratory exercises, homeworks, tests and final exam. Individual work. Consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Introduction. Electricity. Coulombs law. The electric field vector. Potential. Voltage. 7.04 (2.2.2.2.6)
I week exercises
II week lectures	Conductors in electrostatic field. Capacitance. Capacitors. Connecting of capacitor.
II week exercises
III week lectures	Dielectrics. Class of isolation. Dielectrics in the electrostatic field. Electrostatic field energy.
III week exercises
IV week lectures	Direct current. Electrical resistance. Cables. Basic measurements in electrical circuit. 7.04 (2.1.1.1.1 (1)), 7.04 (2.1.1.1 (3)), (2.1.1.1.9), 7.02 (2.1.1.1.1)
IV week exercises
V week lectures	Ohms Law. Joules law. Simple electrical circuits. 7.04 (2.1.1.1.1 (1)), 7.04 (2.1.1.1.1(3)), 7.02 (2.1.1.1.1 )
V week exercises
VI week lectures	Basic measurements in electrical circuit (measurement of the DC voltage and current). Analog and digital instruments for voltage and currents measurement. 7.04 (2.2.2.2.4), 7.04 (2.1.1.1.2 (3))
VI week exercises
VII week lectures	Test I
VII week exercises
VIII week lectures	Kirchhoff laws. Complex circuits. Connecting of resistor. 7.04 (2.1.1.1.1(2))
VIII week exercises
IX week lectures	IX week Sources of electricity. Connecting of sources. Accumulators. Batteries. 7.04 (2.1.1.1.10)
IX week exercises
X week lectures	States Kirchhoff’s laws and uses the laws in solving complex electrical circuits. 7.04 (2.1.1.1.1 (2))
X week exercises
XI week lectures	Node-voltage analysis. Mesh-current analysis.
XI week exercises
XII week lectures	Fundamentals of semiconductor physics. Semiconductors of type P and N. 7.04 (2.1.2.2.1)
XII week exercises
XIII week lectures	Test II
XIII week exercises
XIV week lectures	P -N connections. Diodes. 7.04 (2.1.2.2.2 (1))
XIV week exercises
XV week lectures	Diodes circuit. 7.04 (2.1.2.2.2 (1))
XV week exercises

Student workload	5 credits x 40/30 = 6 hours and 40 minutes Structure: 2 hours of lectures 1 hours of exercises 1 hours of practical exercises 2 hour and 40 minutes of individual work including consultations
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature	1. G. Joksimović: Fundamentals of Electrical Engineering I, Fundamentals of Electrical Engineering II, books (in Montenegrin), 2007. 2. D. Filipović, T. Vučković: Fundamentals of Electrical Engineering, book (in Montenegrin), 1997. 3. D. Filipović, T. V
Examination methods	Two tests up to 10 points during the semester, from 0 to 15 points (up to 30 points in total); Laboratory exercises, from 0 to 10 points; Homework and tests, from 0 to 10 points; Final exam, from 0 to 50 points (10 points practical work); A passing grade is obtained if at least 50 points are collected.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / SHIP'S MEASUREMENTS

Course:

SHIP'S MEASUREMENTS/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
10754	Obavezan	4	4	2+0+2

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
4 credits x 40/30=5 hours and 20 minuts 2 sat(a) theoretical classes 2 sat(a) practical classes 0 excercises 1 hour(s) i 20 minuts of independent work, including consultations	Classes and final exam: 5 hour(s) i 20 minuts x 16 =85 hour(s) i 20 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 5 hour(s) i 20 minuts x 2 =10 hour(s) i 40 minuts Total workload for the subject: 4 x 30=120 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 24 hour(s) i 0 minuts Workload structure: 85 hour(s) i 20 minuts (cources), 10 hour(s) i 40 minuts (preparation), 24 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / ELECTROMAGNETIC COMPATIBILITY OF MARINE EQUIPMENT

Course:

ELECTROMAGNETIC COMPATIBILITY OF MARINE EQUIPMENT/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11264	Izborni	6	6	2+0+1

Programs	MARINE ENGINEERING
Prerequisites	No prerequisites for course enrolment and attending.
Aims	Getting basic knowledge on sources, ways of transmission and impacts of electromagnetic interference on electrical and electronic ship (marine) devices. Getting acquinted with the corresponding standards, measurments and procedures for achieving electromagnetic compatibility.
Learning outcomes	Upon successful completion of the course, the student will be able to: - explain fundamental terms of electromagnetic compatibility; - be familiar with sources and ways of transmission of electromagentic interference; - understand and explain the principles of operation of antennas, antenna parameters and expansion of electromagnetic waves; - understand the basic priciples of electromagnetic protection and earthing; - be familar with electromagnetic compatibility standards.
Lecturer / Teaching assistant	Associate Professor Tatijana Dlabač, PhD; Teaching associate Ivana Čavor
Methodology	Lectures, calculation exercises, homework, consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Concepts of electromagnetic compatibility (EMC), electromagnetic interference (EMI) and electromagnetic sensitivity (EMS)
I week exercises
II week lectures	Electromagnetic fields and electrical circuits
II week exercises
III week lectures	Sources of electromagnetic interference (EMI).
III week exercises
IV week lectures	Transmission of electromagnetic interference
IV week exercises
V week lectures	Antennas. Elementary sources of radiation. The parameters of the antenna and the expansion of electromagnetic waves.
V week exercises
VI week lectures	Measuring antenna.
VI week exercises
VII week lectures	Test I
VII week exercises
VIII week lectures	Electromagnetic shielding
VIII week exercises
IX week lectures	Electromagnetic grounding
IX week exercises
X week lectures	Filtering
X week exercises
XI week lectures	Electromagnetic compatibility measurements and testing
XI week exercises
XII week lectures	Electromagnetic compatibility (EMC) standards.
XII week exercises
XIII week lectures	Standards for harmful impacts of electromagnetic field on ship crew and fuel
XIII week exercises
XIV week lectures	Principles of designing electromagnetically compatible devices
XIV week exercises
XV week lectures	Test II
XV week exercises

Student workload	Per week 6 credits x 40/30 = 8 hours Structure: 2 hours of lectures 1 hours of practice exercises 5 hour of individual work including consultations
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 0 excercises 5 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend classes, do homeworks and make final exam(s).
Consultations
Literature	1. V. Prasad Kodali: Engineering Electromagnetic Compatibility, IEEE Presss, New York, 1996. 2. Williams,T., Armstrong, K.: EMC for Systems and Installations, Newnes, Oxford, 2000. 3. C.R.Paul, Introduction to Electromagnetic Compatibility, John Wiley & Sons, New York, 1992. 4. A. Djordjević, D. Olćan, Ispitivanje elektromagnetske kompatibilnosti, Akademska misao, Beograd, 2012.
Examination methods	Test I, up to 20 points; Test II, up to 20 points; Homework, up to 10 points; Final exam 0 - 50 points; Positive mark requires not less than 50 points cumulatively.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / ELECTROMAGNETIC COMPATIBILITY OF MARINE EQUIPMENT

Course:

ELECTROMAGNETIC COMPATIBILITY OF MARINE EQUIPMENT/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11264	Izborni	6	6	2+0+1

Programs	MARINE ENGINEERING
Prerequisites	No prerequisites for course enrolment and attending.
Aims	Getting basic knowledge on sources, ways of transmission and impacts of electromagnetic interference on electrical and electronic ship (marine) devices. Getting acquinted with the corresponding standards, measurments and procedures for achieving electromagnetic compatibility.
Learning outcomes	Upon successful completion of the course, the student will be able to: - explain fundamental terms of electromagnetic compatibility; - be familiar with sources and ways of transmission of electromagentic interference; - understand and explain the principles of operation of antennas, antenna parameters and expansion of electromagnetic waves; - understand the basic priciples of electromagnetic protection and earthing; - be familar with electromagnetic compatibility standards.
Lecturer / Teaching assistant	Associate Professor Tatijana Dlabač, PhD; Teaching associate Ivana Čavor
Methodology	Lectures, calculation exercises, homework, consultations.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures	Concepts of electromagnetic compatibility (EMC), electromagnetic interference (EMI) and electromagnetic sensitivity (EMS)
I week exercises
II week lectures	Electromagnetic fields and electrical circuits
II week exercises
III week lectures	Sources of electromagnetic interference (EMI).
III week exercises
IV week lectures	Transmission of electromagnetic interference
IV week exercises
V week lectures	Antennas. Elementary sources of radiation. The parameters of the antenna and the expansion of electromagnetic waves.
V week exercises
VI week lectures	Measuring antenna.
VI week exercises
VII week lectures	Test I
VII week exercises
VIII week lectures	Electromagnetic shielding
VIII week exercises
IX week lectures	Electromagnetic grounding
IX week exercises
X week lectures	Filtering
X week exercises
XI week lectures	Electromagnetic compatibility measurements and testing
XI week exercises
XII week lectures	Electromagnetic compatibility (EMC) standards.
XII week exercises
XIII week lectures	Standards for harmful impacts of electromagnetic field on ship crew and fuel
XIII week exercises
XIV week lectures	Principles of designing electromagnetically compatible devices
XIV week exercises
XV week lectures	Test II
XV week exercises

Student workload	Per week 6 credits x 40/30 = 8 hours Structure: 2 hours of lectures 1 hours of practice exercises 5 hour of individual work including consultations
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 0 excercises 5 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations	Students are required to attend classes, do homeworks and make final exam(s).
Consultations
Literature	1. V. Prasad Kodali: Engineering Electromagnetic Compatibility, IEEE Presss, New York, 1996. 2. Williams,T., Armstrong, K.: EMC for Systems and Installations, Newnes, Oxford, 2000. 3. C.R.Paul, Introduction to Electromagnetic Compatibility, John Wiley & Sons, New York, 1992. 4. A. Djordjević, D. Olćan, Ispitivanje elektromagnetske kompatibilnosti, Akademska misao, Beograd, 2012.
Examination methods	Test I, up to 20 points; Test II, up to 20 points; Homework, up to 10 points; Final exam 0 - 50 points; Positive mark requires not less than 50 points cumulatively.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE AND COASTAL ENVIRONMENTAL PROTECTION

Course:

MARINE AND COASTAL ENVIRONMENTAL PROTECTION/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11294	Obavezan	5	4	2+1+1

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
4 credits x 40/30=5 hours and 20 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 1 hour(s) i 20 minuts of independent work, including consultations	Classes and final exam: 5 hour(s) i 20 minuts x 16 =85 hour(s) i 20 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 5 hour(s) i 20 minuts x 2 =10 hour(s) i 40 minuts Total workload for the subject: 4 x 30=120 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 24 hour(s) i 0 minuts Workload structure: 85 hour(s) i 20 minuts (cources), 10 hour(s) i 40 minuts (preparation), 24 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARINE AND COASTAL ENVIRONMENTAL PROTECTION

Course:

MARINE AND COASTAL ENVIRONMENTAL PROTECTION/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11294	Obavezan	5	4	2+1+1

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
4 credits x 40/30=5 hours and 20 minuts 2 sat(a) theoretical classes 1 sat(a) practical classes 1 excercises 1 hour(s) i 20 minuts of independent work, including consultations	Classes and final exam: 5 hour(s) i 20 minuts x 16 =85 hour(s) i 20 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 5 hour(s) i 20 minuts x 2 =10 hour(s) i 40 minuts Total workload for the subject: 4 x 30=120 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 24 hour(s) i 0 minuts Workload structure: 85 hour(s) i 20 minuts (cources), 10 hour(s) i 40 minuts (preparation), 24 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / SIMULATOR AND NAVIGATION EXERCISES

Course:

SIMULATOR AND NAVIGATION EXERCISES/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11298	Obavezan	5	4	0+0+3

Programs	MARINE ENGINEERING
Prerequisites	No.
Aims	Prepare students for onboard practice, in accordance with STCW and SOLAS conventions.
Learning outcomes	Upon successful completion of this subject the student will be able to demonstrate: - General knowledge and master basic methods, techniques, and skills that are necessary for handling marine engine systems, main engines, auxiliary engines and generators, boilers, separators, compressors, steering gear and other machinery onboard vessels at management level, in accordance with the requirements of STCW. All these systems are accessible in the existing simulators and onboard available vessels.
Lecturer / Teaching assistant	Professor Prof. Dr. Lazo Vujovic c-eng Assistant Mr. Miroslav Vukicevic c-eng
Methodology	Lecture, practical exercises, homework, consultation, practical wor on simulator and fieldwork.

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises	Preparation and semester enrolment Familiarisation with marine engine simulator, its purpose and objectives.
II week lectures
II week exercises	Description of the plant (list of machinery and associated systems – storage tanks, valves, pipeline systems, pumps, heat exchangers, fuel system, filters, electric generators, steam plant, main propulsion plant, control from the engine room, remote control of the propulsion unit).
III week lectures
III week exercises	Measurement gauges (pressure, temperature, level, volume- mass, flow, engine speed, power, voltage and electric power, CO2 and NOx contents, indicator diagram).
IV week lectures
IV week exercises	Description of the simulated alarms. Calculation of the shaft torque, mean indicated pressure, cylinder power, mechanical efficiency of the engine, and specific fuel consumption. Work on ME
V week lectures	The First Compulsory Assignment ( start diesel generators and emergency generator)
V week exercises
VI week lectures
VI week exercises	Control. Performing local and remote control systems (control from the engine room, E/R control room and the navigating Bridge).
VII week lectures	Hand-over of the control point.
VII week exercises	Operation procedures. Preparation and starting. ( Aux. Boilers, manually and automatic work)
VIII week lectures	The Second Compulsory Assignment (Aux. Boiler start manually)
VIII week exercises	Hand-over of the control point.
IX week lectures
IX week exercises	Operation procedures. Preparation and starting. ME .
X week lectures
X week exercises	Safety measures taken when starting and controlling: valves, pumps, water system, steam plant system, burners, fuel tanks make-up, Centrifugal pumps, bilge tanks.
XI week lectures
XI week exercises	Using checklist when preparing, starting and controlling individual engines and systems. Conditions of connecting electric generators and their parallel operation (speed, voltage, frequency and synchronisation). Description of the operation of a simulated plant, checklist of procedures for: closing and opening the valves within the system, flow of sea water, starting the steam generating plant, fuel separator operation
XII week lectures
XII week exercises	Unplanned maintenance. Detection of malfunction / failure and procedure of removing the failure. Duties of the 1st marine engineer – to advice and promptly notify the navigating bridge about potential problems in the propulsion unit.
XIII week lectures
XIII week exercises	Planned maintenance
XIV week lectures	Final Examination ( Locally start of Main engine)
XIV week exercises
XV week lectures	Seminar work, homework explanation.
XV week exercises	Semester verification and mark registration

Student workload	5 credits x 40/30 = 6 hours + 40 minutes
Per week	Per semester
4 credits x 40/30=5 hours and 20 minuts 0 sat(a) theoretical classes 3 sat(a) practical classes 0 excercises 2 hour(s) i 20 minuts of independent work, including consultations	Classes and final exam: 5 hour(s) i 20 minuts x 16 =85 hour(s) i 20 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 5 hour(s) i 20 minuts x 2 =10 hour(s) i 40 minuts Total workload for the subject: 4 x 30=120 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 24 hour(s) i 0 minuts Workload structure: 85 hour(s) i 20 minuts (cources), 10 hour(s) i 40 minuts (preparation), 24 hour(s) i 0 minuts (additional work)
Student obligations	Students are obliged to attend lectures, submit homework assignments and take final exam
Consultations	Every day after exercise.
Literature	1. Instruction manual of marine simulator of tanker ship Transas 6S60MC 2. nstruction manual of marine simulator of tanker ship Transas 6S50MC 3. Gorski Z., Construction and operation of marine hydraulic machinery. Trademar. Gdynia 2008. 4. Gorski Z., Construction and operation of marine pumps. Trademar. Gdvnia 2012.
Examination methods	1. Practical exercise I, from 0 to30 points; 2. Practical exercise I, from 0 to 30 points; 3. Final exam, from 0 to 30 points; 4. Homework 10 points Passing mark is awarded if the student collects more than 50 points.
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / ORGANIZATION OF WORK AND SHIPBOARD MANAGEMENT

Course:

ORGANIZATION OF WORK AND SHIPBOARD MANAGEMENT/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11299	Obavezan	6	6	2+1+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 1 excercises 5 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / ORGANIZATION OF WORK AND SHIPBOARD MANAGEMENT

Course:

ORGANIZATION OF WORK AND SHIPBOARD MANAGEMENT/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11299	Obavezan	6	6	2+1+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 1 excercises 5 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARITIME MARKET RESEARCH

Course:

MARITIME MARKET RESEARCH/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11302	Izborni	5	6	3+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 3 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 3 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARITIME MARKET RESEARCH

Course:

MARITIME MARKET RESEARCH/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11302	Izborni	5	6	3+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 3 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 3 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / SHIP MAINTENANCE MANAGEMENT

Course:

SHIP MAINTENANCE MANAGEMENT/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11306	Obavezan	5	5	2+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
5 credits x 40/30=6 hours and 40 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 2 hour(s) i 40 minuts of independent work, including consultations	Classes and final exam: 6 hour(s) i 40 minuts x 16 =106 hour(s) i 40 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 6 hour(s) i 40 minuts x 2 =13 hour(s) i 20 minuts Total workload for the subject: 5 x 30=150 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 30 hour(s) i 0 minuts Workload structure: 106 hour(s) i 40 minuts (cources), 13 hour(s) i 20 minuts (preparation), 30 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARITIME SAFETY AND RISK MANAGEMENT

Course:

MARITIME SAFETY AND RISK MANAGEMENT/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11307	Obavezan	6	6	2+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 4 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / MARITIME SAFETY AND RISK MANAGEMENT

Course:

MARITIME SAFETY AND RISK MANAGEMENT/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11307	Obavezan	6	6	2+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 4 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / TECHNICAL SURVEY AND CLASSIFICATION

Course:

TECHNICAL SURVEY AND CLASSIFICATION/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11308	Obavezan	6	6	2+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 4 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / ECONOMY OF SHIP EXPLOITATION

Course:

ECONOMY OF SHIP EXPLOITATION/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11309	Obavezan	6	6	2+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 4 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points

Faculty of Maritime Studies / MARINE ENGINEERING / ECONOMY OF SHIP EXPLOITATION

Course:

ECONOMY OF SHIP EXPLOITATION/

Course ID	Course status	Semester	ECTS credits	Lessons (Lessons+Exercises+Laboratory)
11309	Obavezan	6	6	2+2+0

Programs	MARINE ENGINEERING
Prerequisites
Aims
Learning outcomes
Lecturer / Teaching assistant
Methodology

Plan and program of work
Preparing week	Preparation and registration of the semester
I week lectures
I week exercises
II week lectures
II week exercises
III week lectures
III week exercises
IV week lectures
IV week exercises
V week lectures
V week exercises
VI week lectures
VI week exercises
VII week lectures
VII week exercises
VIII week lectures
VIII week exercises
IX week lectures
IX week exercises
X week lectures
X week exercises
XI week lectures
XI week exercises
XII week lectures
XII week exercises
XIII week lectures
XIII week exercises
XIV week lectures
XIV week exercises
XV week lectures
XV week exercises

Student workload
Per week	Per semester
6 credits x 40/30=8 hours and 0 minuts 2 sat(a) theoretical classes 0 sat(a) practical classes 2 excercises 4 hour(s) i 0 minuts of independent work, including consultations	Classes and final exam: 8 hour(s) i 0 minuts x 16 =128 hour(s) i 0 minuts Necessary preparation before the beginning of the semester (administration, registration, certification): 8 hour(s) i 0 minuts x 2 =16 hour(s) i 0 minuts Total workload for the subject: 6 x 30=180 hour(s) Additional work for exam preparation in the preparing exam period, including taking the remedial exam from 0 to 30 hours (remaining time from the first two items to the total load for the item) 36 hour(s) i 0 minuts Workload structure: 128 hour(s) i 0 minuts (cources), 16 hour(s) i 0 minuts (preparation), 36 hour(s) i 0 minuts (additional work)
Student obligations
Consultations
Literature
Examination methods
Special remarks
Comment

Grade:	F	E	D	C	B	A
Number of points	less than 50 points	greater than or equal to 50 points and less than 60 points	greater than or equal to 60 points and less than 70 points	greater than or equal to 70 points and less than 80 points	greater than or equal to 80 points and less than 90 points	greater than or equal to 90 points