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Course Contents

COMPULSORY COURSES
FIRST YEAR 1. SEMESTER
No Course Code COURSE TITLE   C/E T P C ECTS  
   
1. EMB113 Introduction to Energy Engineering   C 3 0 3 4  
 What is an engineer? Engineering branches. Introduction to Energy Systems Engineering. Engineering ethics. Statistics. Metric units and unit conversions. Newton's laws. Materials science. Manufacturing methods. Introduction to thermodynamics. Heat transfer. Technical field trip. Energy sources, historical development of energy technology, steam energy and machinery, internal combustion engines, power plants, energy statistics, renewable energy, nuclear energy, new approaches to energy production, conventional energy sources, and advances in science and technology.  
2. EMB109 COMPUTER AIDED DRAWING I   C 2 2 4 5  
Introduction to computer-aided drawing. Basic technical drawing steps and projection techniques. Sectional view rules. Fundamental concepts in three-dimensional modeling. Three-dimensional part design and solid modeling. Creation of two-dimensional technical drawings from three-dimensional models and detailing. Assembly modeling and assembly of parts. Surface modeling. Computer-aided design (CAD) and its applications.  
3. EMB105 MATHEMATICS I   C 3 0 3 4  
Line and Plane in Space. Sets, Number Sets. Functions, Composite Function, Inverse Function, Limit, Limits of Functions, Uncertainty at Limits, Continuity of Functions, Matrices, Determinants, Cramer's Rule, Systems of Linear Equations, Vectors, Vector Space, Eigenvalues and Eigenvectors, Linear Transformations. Derivative, Applications of Derivatives, Exponential and Logarithmic Functions, Trigonometric and Hyperbolic Functions. Complex Numbers. L'Hospital's Rule.  
4. EMB107 PHYSICS I   C 3 0 3 4  
Vectors, Motion in One Dimension, Motion in Two Dimensions, Circular Motion and Other Applications of Newton's Law, Work and Energy, Potential Energy and Conservation of Energy, Linear Momentum and Collisions, Rotation of Rigid Objects About an Axis, Rolling Motion, Angular Momentum and Torque, Static Equilibrium and Elasticity, Oscillatory Motion.  
5. ENF I BASIC INFORMATION TECHNOLOGIES   C 2 2 4 4  
Fundamental information about computer systems, introduction to computer hardware and software, DOS and WINDOWS operating systems, word processing, database use, presentation preparation, spreadsheet and graphic applications, the internet and its uses, and HTML and JAVA programming.  
6. AIT101 ATATURK'S PRINCIPLES AND REVOLUTION HISTORY I   C 2 0 2 2  
Renovation movements in the Ottoman Empire in the late 19th century and the general state of the Ottoman Empire in the early 20th century. The Tripoli and Balkan Wars. World War I. An overview of World War I, the Ottoman Empire at war. The Armistice of Mudros, preparations for the War of Independence. The Erzurum Congress. The Sivas Congress. The opening of the Grand National Assembly in Ankara. The establishment of the Grand National Assembly Government, internal rebellions.  
7. YD103 FOREIGN LANGUAGE I (ENG)   C 2 1 3 5  
Countable and uncountable nouns, adverbs of time, indefinite pronouns, imperatives, prepositions of time, exclamatory expressions, adverbs of frequency, inflected auxiliary verbs, colors, days, months, and related text studies. Present tense and past participle with the verb to be. Use of the structure (have got) with examples.  
8. TD101 TURKISH LANGUAGE I   C 2 0 2 2  
What is language? The place and importance of language as a social institution in national life. The relationship between language and culture. The status of the Turkish language among world languages and its distribution areas. Sounds in Turkish and their classification. The sound characteristics of Turkish and the rules related to phonetics. Syllable information, spelling rules and their application, punctuation and their application.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
Second Semester  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMB102  MATHEMATICS II   C 3 0 3 4  
Sequences, series, power series. Binomial, Taylor series. Expansions of functions into Taylor and Maclaurin series, Parametric analysis of curves. Polar analysis of curves. Indefinite integral. Rules of integration. Definite integral and its applications, Solutions of second-order linear equations with constant and variable coefficients. Functions of several variables, Partial derivatives, Finding maximums and minimums (Langrange multiplier method). Multiple integrals, Calculation of area and volume by integration, Line integral.  
2. EMB120 GENERAL CHEMISTRY   C 3 0 3 4  
 Chemical relations, chemical reactions, gases, thermochemistry, electron structure of the atom and periodic atomic properties, chemical bonds, liquids, solids and intermolecular forces, solutions, chemical equilibrium, acids, bases and aqueous solution equilibria, thermodynamics, electrochemistry, radioactivity, organic chemistry.  
3. EMB116 COMPUTER AIDED DRAWING II   C 1 2 3 5  
Fundamental concepts in three-dimensional modeling. Three-dimensional part design and solid modeling. Creation and detailing of two-dimensional technical drawings from three-dimensional models. Assembly modeling and assembly of parts. Surface modeling. Computer-aided design (CAD) and its applications.  
4. EMB108 PHYSICS II   C 3 0 3 4  
 Charged matter and electric fields. Gauss's law, electric potential. Capacitance and capacitors, current and resistance. Electromotive force, circuits, and magnetic fields. Ampere's law and Faraday's law of induction. Inductance and the magnetic properties of matter. Electromagnetic waves  
5. EMB114 COMPUTER PROGRAMMING   C 1 2 3 4  
 C functions, Variables, Constants, Operators, Program control statements, Library functions, Arrays, Pointers, Bit operators, Files.  
6. AIT102 ATATURK'S PRINCIPLES AND HISTORY OF REVOLUTION II   C 2 0 2 2  
The Paris Peace Conference. The Occupation of Izmir. The internal situation of the country and minorities. The Circassian Ethem Incident. The First and Second Battles of İnönü. The Battle of Sakarya and its consequences. The Treaties of Kars and Ankara. The Great Offensive. The Mudanya Armistice, its principles and significance. The Lausanne Conference and its significance. The Turkish Revolution; reforms in political, legal, social, cultural, and educational fields. The transition to the multi-party system. Developments in the economic sphere. Turkish Foreign Policy. The Armenian question. World War II and Türkiye. Atatürk's Principles.  
7. YD104 FOREIGN LANGUAGE II (ENG)   C 2 1 3 5  
Subject pronouns, possessive adjectives, nouns and their plurals, demonstrative adjectives, and some adverbs. Present tense, the relative tense of being, and its affirmative, negative, and interrogative forms. Conjunctions, demonstrative pronouns, definite and indefinite article descriptions, verbal nouns, and object pronouns. The uninflected auxiliary verb "can" and its use with examples.  
8. TD102 TURKISH LANGUAGE II   C 2 0 2 2  
Derivative suffixes in Turkish and their application. Rules related to composition, plan and application for writing compositions. Conjugation of nouns and verbs in Turkish. Forms of expression in composition and their application. Usage of adverbs and prepositions in Turkish.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
Third Semester  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMB201 ENGINEERING MECHANICS I   Z 3 0 3 5  
Fundamental Concepts. Newton's Laws, Units, Law of Gravitation, Vector Operations. Statics of Particles; Plane Force System, Space Force System. Rigid Bodies and Equivalent Force Systems. Equilibrium of Rigid Bodies. Centers of Gravity of Distributed Forces. Analysis of Structural Systems. Truss Systems, Frames, and Machines. Friction. Moments of Inertia of Distributed Forces; Moments of Inertia of Areas and Masses. Virtual Work Method.  
2. EMB203 MATERIAL INFORMATION   Z 3 0 3 5  
Introduction to materials science. Atomic structure. Crystal structures. Defects in solids. Diffusion. Mechanical tests: Tensile test, Hardness test, Impact test, Fatigue test, Creep test. Physical properties of materials: Electrical, Thermal and Magnetic Properties, Corrosion.  
Phases and phase diagrams: Binary isomorphic phase diagrams, binary eutectic phase diagrams, iron-carbon phase diagram. Phase transformations, heat treatments of metal alloys, structure and properties of metals and alloys, structure and properties of ceramic materials, structure and properties of polymer materials, structure and properties of composite materials. Physical properties of materials, chemical composition, atomic bond structures, crystal planes and directions, Bravais and Miller indices, structural defects and their effects on the properties of crystalline materials, understanding and measuring the mechanical properties of materials, defining the effect of diffusion on the chemical composition and mechanical properties of crystalline materials and one-dimensional problems, two-component phase diagrams, principles of solidification and diffusion in alloy systems, structure-property relationships in metals, ceramics, polymers and composite materials, types of corrosion, protection methods.  
3. EMB205 THERMODYNAMICS   Z 3 0 3 5  
Introduction to thermodynamics: A detailed introduction to the purpose, classification, and application areas. Fundamental concepts: thermodynamic systems (open, closed, adiabat, diabat) and their properties, energy and classification (storage, transition, macroscopic, microscopic energies), thermal energy and mechanical energy, temperature and pressure (definition, properties, and measurement principles). Dimensions and units: Dimensions and units of basic quantities, unit systems, the SI unit system (base, supplementary, and derived SI units), unit analysis. Thermodynamic properties of pure substances: Definition and classification of properties, specific quantities (density, specific gravity, internal energy, enthalpy, entropy), phase change phases of pure substances (solid, liquid, vapor) and their diagrams, behavior of gases and equations of state (ideal gases, real gases). Principles of conservation of mass and energy: General mass and energy conservation equations, solution of closed systems, solution of open systems (steady, steady, and unsteady flows). The First Law of Thermodynamics and its applications: General equation and its derivation, specialization of closed and open system equations, state changes (constant volume, constant pressure, constant temperature, adiabatic and polytropic), derivation of state change relations in ideal gases and their application in engineering problems.  
4. EMB207 BASIC ELECTRICITY   Z 3 0 3 5  
Fundamentals of electrical engineering. Circuit analysis. Alternating current circuits and power. Frequency response and transients. RL, RC, RLC circuits. Study of semiconductor circuit technology. Study of diode and transistor circuit elements. Operational amplifiers. Digital electronics. Inverting and noninverting digital electronic circuits. Fundamentals of electrical machines. Motors and generators. Fundamentals of electrical engineering. Circuit analysis. Alternating current circuits and power. Frequency response and transients. Electronic circuits. Semiconductors and diodes. Transistors and amplifiers. Operational amplification. Digital electronics. Electrical machines. Fundamentals of electromechanics.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
4th Semester  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMB204 MEASUREMENT TECHNIQUE   Z 3 0 3 5  
Measurement and fundamental concepts in engineering. Basic analog and digital electronics. Fourier techniques. Basic concepts of methods and sensors for measuring size, pressure, flow, temperature, heat, force, strain, vibration, and sound. Errors in measurement and measuring instruments. Uncertainty and statistical analysis of experimental data. Graphical and mathematical data analysis. Basic concepts of measurement. Uncertainty and statistical analysis of experimental data. Basic analog electronics. Fourier techniques. Digital electronics. Basic concepts of methods and sensors for measuring size, pressure, flow, temperature, heat, force, strain, vibration, and sound. Uncertainty and statistical analysis of experimental data. Report writing and presentation.  
2. EMB206 THERMODYNAMICS II   Z 3 0 3 5  
Second Law of Thermodynamics: Reversible and irreversible processes, Carnot's principle, Carnot heat and refrigeration engines, entropy and exergy: Clausius equation and entropy, the principle of increase of entropy, entropy calculation methods, determination of entropy changes in ideal gases, concept of exergy, exergy change of a system, exergy solutions for open and closed systems. Gas cycles: Cycle principles, cycle thermal efficiency, Otto cycle, diesel cycle, other gas cycles (Stirling, Ericsson, and Brayton). Steam cycles and thermal power plants: Carnot steam cycle, Rankine cycle, Molier hs diagram, thermal power plant elements, thermodynamic solution of power plants, cogeneration. Gas mixtures and combustion solution.  
3. EMB208 BASIC ELECTRONICS   Z 3 0 3 5  
Fundamentals of electrical engineering. Circuit solution. Alternating current circuits and power. Frequency response and transients. RL, RC, RLC circuits. Examination of semiconductor circuit technology. Examination of diode and transistor circuit elements. Operational amplifiers. Digital electronics. Inverting and noninverting digital electronic circuits. Fundamentals of electrical machines. Motors and generators. Basic electrical concepts; current, voltage, power, energy, work, electric field, Basic electrical laws; Ohm's law, Kirchhoff's laws, Electrical/electronic circuit elements; Analog and digital ammeters, voltmeters, ohmmeters structures, operating principles and use; current, voltage, resistance, dB, inductance, capacitance, power, beta current gain measurement and control of semiconductor elements. Oscilloscope structures, operating principles and use; frequency, period, phase difference measurement, Signal generators; use, sine, square, triangle, sawtooth signals, frequency adjustment, amplitude adjustment, Electrical/electronic circuit elements tests; Reading electronic circuit diagrams, series, parallel, series-parallel and mixed, resistance, coil and capacitor circuits, rectifier circuits, passive filter and regulator circuit applications, printed circuit board drawing, top and bottom view drawing, methods of transferring the printed circuit board to the board, drilling the board, soldering iron and solder properties, solder pump, soldering techniques.  
4. EMB212 ENERGY RESOURCES   Z 3 0 3 5  
Wind energy, wind energy potential, wind energy map of Türkiye, solar energy, solar energy potential, passive solar energy, active solar energy, geothermal energy, geothermal energy potential in Türkiye, bioenergy, biomass potential, mini hydropower and its potential, energy production from waste: energy production from solid fuels, energy savings and opportunities, biodiesel potential and production. Includes an introductory section on basic energy terms, fuel cells, electrolyzers, and hydrogen production processes from biomass, as well as mechanical heat engines, hydrogen energy, solar, wind, and hydropower. Introduction to thermal power plants and energy conversion systems. Information on the design of various types of thermal power plants. Understanding heat production processes. Teaching the main structural elements of thermal power plants.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
5th Semester  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMB201 HEAT TRANSFER   Z 3 0 3 5  
Heat conduction in one and two dimensions in flat plates, cylindrical, and spherical bodies in steady and unsteady regimes. Cases containing internal heat sources; heat transfer in multilayered bodies. Application of numerical methods in heat conduction problems, fins. Thermal radiation, heat radiation between black and gray surfaces, shape factors, radiation shielding, gas radiation. Hydrodynamics and thermal boundary layers. Natural and forced heat convection. Dimensionless numbers; Reynolds analogy. Flow in pipes and tube bundles. Evaporation and condensation. Heat exchangers; the effectiveness method. Mass transfer and its laws. Similarities between heat and mass transfer. Convection and convection mass transfer. Forced convection heat transfer in pipes and flow around bodies. Free convection heat transfer around bodies and in empty volumes. Film and droplet condensation. Boiling in static media and forced convection. Radiation in gases and solids. Heat transfer by convection and radiation. Heat exchangers. Mass transfer.  
2. EMB303 FLUID MECHANICS I   Z 3 0 3 5  
Definition of fluid mechanics, some physical properties of fluids: Density, pressure, temperature, viscosity, surface tension. Fundamental principles of fluid motion: Control surface/volume, relativity of motion, stages of fluid motion, dimensionless parameters of flow (Reynolds, March, Froude numbers), model-reality analogy, dimensional solution and application. General definitions, fluid mechanics and hydraulics, units, viscosity, hydrostatic force acting on plane surfaces, fluid flow, steady and uniform flow, flow charts, continuity program writing, introduction to its operation, input-output statements, control statements, ready-made functions, filing operations and commands, program examples. Momentum equation, dimensional analysis and similarity, viscous flows in pipes and channels, boundary-layer theory, potential flow theory, compressible flow, flow measurement techniques.  
3. EMB307 SOLAR ENERGY SYSTEMS   Z 3 0 3 5  
 Basic definitions. Solar energy applications. Use of solar energy in direct power generation. Storage through conversion. Fundamental information and equations. Solar geometry and solar radiation. Different types of solar collectors and their applications. Collector elements. Heat transfer. Collector thermal calculations. Solar water heating systems. Open and closed systems with natural circulation and pumps. Sample project. Solar cooling systems. Mechanical and non-mechanical systems. Other systems utilizing solar energy.  
4. EMB311 ENERGY COST ANALYSIS   Z 3 0 3 5  
Introduction to engineering economics and its fundamental concepts. Market conditions and demand forecasts. Cost concepts. Interest rates and cash flow sequences. Balance sheet analysis. Depreciation and amortization methods. Economic models in engineering. Investment decisions and evaluation of investment options. Feasibility testing. SWOT analysis. Investment decisions under uncertainty. Cost-benefit analysis. Applications of engineering economics. Gaining knowledge of energy management, examining economic analysis methods, and determining investment costs, operating costs, and payback periods with examples of energy efficiency applications.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
6th Semester  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMBB302 MACHINE ELEMENTS   Z 3 0 3 5  
Introduction, loading and stress analysis, failures resulting from static loading, fatigue failures resulting from variable loading, design of bolts, connections and detachable joints, design of welding, soldering, bonding and permanent joints, mechanical springs, rolling bearings, lubrication and bearings, gears – common spur and helical gears, clutches, brakes, couplings and flywheels, flexible mechanical elements, shafts and axles.  
2. EMB304 FLUID MECHANICS II   Z 3 0 3 5  
Two- and three-dimensional flows, the propagation of disturbances in fluids, and the concept of "motion-following derivatives." Two-dimensional, inviscid, steady-state flow. Euler's equations, potential flow, irrotational flow concepts, complex potential. Some special flow forms: uniform flow, flow in a corner, simple vortex, source/sink doublet, flow around a circular cylinder. Drag and lift generation. Two-dimensional, viscous, steady flow: Navier-Stokes equations, the concept of vorticity, Coette flow, Poiseuille flow. The effect of Reynolds number on flow. Boundary layer theory: derivation of Prandtl's equations, friction, separation, and reattachment around a plane plate.  
3. EMB306 ENERGY ANALYSIS IN BUILDINGS   Z 3 0 3 5  
Determination of heat loss and gain in buildings. Artificial and natural energy sources in buildings. Thermal analysis of buildings under comfort and industrial operating conditions, energy equations and solutions. Insulation and energy saving studies.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
7th Semester  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMB429 GRADUATION PROJECT   Z 0 2 1 6  
All final year students are required to prepare a design-oriented project on a subject related to Energy and Plumbing Engineering under the supervision of their advisors, to evaluate alternatives and analyze all results, and to present and defend a report with details of any necessary drawings.  
2. EMB433 ENERGY LABORATORY   Z 0 2 1 5    
This laboratory includes experiments related to heat transfer, thermodynamics, materials, mechanical and applied fluid mechanics, power systems, and energy. These experiments aim to examine and observe various factors related to energy engineering.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
8th Semester  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMB404 GRADUATION THESIS   Z 0 2 0 6  
Using the knowledge and skills they have acquired during their Energy Systems Engineering education, students will conduct theoretical and/or experimental studies on a subject related to Energy Systems Engineering under the supervision of their advisors, and present the results obtained in this context as a detailed report.  
2. EMB418 HIGH VOLTAGE TECHNIQUE   Z 3 0 3 5  
Introduction to static electric fields; basic electrode systems, approximate calculation of electric field intensity; layered electrode systems, conformal transformations; discharge phenomena in solids, liquids and gases (Townsend and channel theories); corona, lightning and surface discharge; overvoltages and protection against overvoltages; generation and measurement of high voltages.  
3. EMB432 ENERGY EFFICIENCY AND MANAGEMENT   Z 1 2 2 5  
The aim is to provide competence in topics such as examining the economic, technological, political, and environmental dimensions of energy, energy systems, energy and economic growth, energy demand and energy conservation, international energy markets, determining a national energy policy, energy conservation research and analysis methods, waste heat recovery, economic solution methods, thermal insulation, energy and mass balances, and combustion methods. Türkiye's general energy status, energy needs, the structure of Turkish industry, the importance of energy consumption and energy savings, the consumption-cost relationship, the energy management program. Introduction to heat economics. Costs in thermal power plants. Energy costs. Insulation, insulation techniques. Fuels, fuel heat values, combustion. Reheating, heat transfer, heat exchangers. Cycle efficiencies. Heat balance. General information on energy efficiency, energy efficiency in industry, high-efficiency engines, compressed air systems, heat recovery systems, comparison of fuels, fuels  
comparison, increasing efficiency in boilers, optimizing the air-fuel ratio in boilers, heating the combustion air in boilers, insulation of hot and cold surfaces, high-efficiency lighting.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
ELECTIVE COURSES  
Third Semester Elective Courses  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMB 217 Numerical Methods in Engineering   E 1 2 3 5  
Introduction to Numerical Methods. Matrices and Determinants. Numerical Solutions of Systems of Linear Algebraic Equations. Solutions of Nonlinear Equations. Interpolation and Approximate Solutions. Lagrange's Method. Solutions of Systems of Nonlinear Equations by Newton's Method. Finite Difference Method. Numerical Differentiation. Numerical Integration. Numerical Solutions of Difference Equations. Runge-Kutta Method. Euler's Method. Integration by Using Taylor Series. Sample solutions with packages such as Mathematica, Mathcad, etc.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
IV. Semester Elective Courses  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMB220 Statistical Methods in Engineering II   E 3 0 3 5  
Basic statistical knowledge, variance analysis, distribution creation and data processing techniques, using statistical package programs, creating and applying subject groups, examining t-tests and anova tests, significance and validity levels.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
5th Semester Elective Courses  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMB 307 Solar Energy Systems   E 3 0 3 5  
Basic definitions. Solar energy applications. Use of solar energy in direct power generation. Storage through conversion. Fundamental information and equations. Solar geometry and solar radiation. Different types of solar collectors and their applications. Collector elements. Heat transfer. Collector thermal calculations. Solar water heating systems. Open and closed systems with natural circulation and pumps. Sample project. Solar cooling systems. Mechanical and non-mechanical systems. Other systems utilizing solar energy.  
2. EMB 311 Energy Cost Analysis   E 3 0 3 5  
This course covers an introduction to engineering economics and its fundamental concepts. Market conditions and demand forecasts. Cost concepts. Interest rates and cash flow sequences. Balance sheet analysis. Depreciation and amortization methods. Economic models in engineering. Investment decisions and evaluation of investment options. Feasibility testing. SWOT analysis. Investment decisions under uncertainty. Cost-benefit analysis. Engineering economics applications. Gaining knowledge about energy management, examining economic analysis methods, and determining investment costs, operating costs, and payback periods with examples of energy efficiency applications.  
3. EMB 319 Fuel Cells   E 3 0 3 5  
Definitions, Historical Development. Emissions; Overview of Fuel Cell Systems; Alkaline Fuel Cell. Operating Conditions and Principles of Molten Carbonate Fuel Cells, Solid Oxide Fuel Cells, and Solid Polymer Fuel Cells; Typical Cell Materials, Cell Configurations, Applications, and Economics; Principles of Fuel Cell Electrochemistry; Fuel Cell Temperatures. Adiabatic Flame Temperature. Chemical Equilibrium Criteria, Equilibrium Constants. Chemical Kinetics: Reaction Rates, Arrhenius Relations. Activation Energy. Single-Stage, Sequential, and Chain Reactions. Droplet and Spray Combustion. Combustion Systems, Fuel Atomization, Group Combustion Numbers. Fluidized Bed Combustion. Coal Combustion. Ignition, Pollutant Release from Combustion  
4. EMB313 NUCLEAR ENERGY   E 3 0 3 5  
Atomic structure. Binding energy. Radioactive decay. Nuclear reactions. Fission. Fusion. Neutron interactions. Cross sections. Steady-state thermal reactor solution. Diffusion equation and its solutions. Four-factor equation. Criticality calculations. Transient thermal reactor solution. Nuclear reactors and their components. Fission reactors (Pressurized water reactors, Boiling water reactors, Heavy water reactors, Gas-cooled reactors, Fast breeder reactors, Advanced fission reactors). Fusion reactors. Hybrid reactors.  
5. EMB 315 Energy and Environment   E 3 0 3 5  
Energy sources, fossil fuels, combustion products, air pollution, global warming, nuclear energy, hydroelectric energy, solar energy, wind energy, wave energy, biological fuel, energy conservation, energy policies  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
6th Semester Elective Courses  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMB308 Wind Energy Systems   E 3 0 3 5  
History of wind energy, wind energy potentials and determination methods. Examination of wind turbines, wind power calculation  
2. EMB310 Heat Recovery Systems   E 3 0 3 5  
Heating and air conditioning systems, heat recovery systems used in industry.  
3. EMB 312 Power Transmission and Distribution   E 3 0 3 5  
To teach the fundamentals of electricity generation, electrical energy transmission methods, components and introduction of the electrical distribution system, basic parameters of transmission lines and equivalent circuits of transmission lines.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
7th Semester Elective Courses  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMB405 Energy Storage Systems   E 3 0 3 5  
Thermal energy storage systems, electrical energy storage systems, electrochemical energy storage systems, hydrogen energy storage systems. Batteries, battery components, battery classification, battery types, battery comparison, battery charge testing, battery specifications, industrial applications. Overview of Fuel Cell Systems; Alkaline Fuel Cell. Molten Carbonate Fuel Cell, Solid Oxide Fuel Cell, and Solid Polymer Fuel Cells. Thermal energy storage and systems, supercapacitors, superconducting magnetic energy storage; definition of superconductivity, applications of superconductivity, superconducting magnetic energy storage systems.  
2. EMB 407 Automatic Control Systems   E 3 0 3 5  
Fundamentals of automatic control. Control systems terminology. Basic automatic control  
elements. HVAC/R applications. Digital control system applications. Automatic control system design. Control circuit diagrams and application examples.  
3. EMB411 Heating and Ventilation Systems   E 3 0 3 5  
Introduction, history of heating, introduction to various heating systems. Boilers used in heating systems, safety systems, layout of boiler rooms, chimneys. Burners and their calculations. Heaters and heater selection. Hot water heating systems. Sample solutions for heat calculations. Pipe calculations. Ventilation systems. Design principles of heating systems. Psychrometric charts. Winter and summer air conditioning.  
4. EMB413 Electrical Machines and Drives   E 3 0 3 5  
Basic operating principles of electrical machines, transformers, DC generators and motors, AC motors, asynchronous motors and power, loss, torque characteristics.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
   
8th Semester Elective Courses  
No Course Code COURSE TITLE   C/E T P TS ECTS  
   
1. EMB410 Power Plants and Engineering   E 3 0 3 5  
Energy sources and their classification, principles of electrical energy production, types of power plants, Rankine and Brayton cycles, steam turbine systems, gas turbine systems, combined systems, fuels used in thermal power plants, emissions from thermal power plants, thermal efficiency and ways to improve them, nuclear power plants.  
2. EMB412 Hydrogen Energy Systems   E 3 0 3 5  
Classical and renewable energy sources, properties of hydrogen, obtaining hydrogen as fuel and converting it into energy, storing and transporting hydrogen, hydrogen technologies, fuel cells, advantages and disadvantages of hydrogen energy.  
3. EMB416 Heat Exchangers   E 3 0 3 5  
Heat exchanger types and properties. Classification of heat exchangers. Methods used in heat exchanger analysis: Heat exchanger effectiveness-number of pass units, logarithmic mean temperature difference, temperature effectiveness-number of pass units depending on cold side fluid variables, temperature difference ratio-temperature efficiency methods. Pressure drop and pumping power in heat exchangers. Fouling in heat exchangers. Compact heat exchangers. Heat exchanger applications: Condensers, evaporators, heaters, economizers, and cooling towers. Types and calculations of recuperative heat exchangers. Classification of heat exchangers. Tube-bundle heat exchangers. Liquid-liquid plate heat exchangers. Cross-flow plate gas-gas heat exchangers. Finned gas-liquid heat exchangers. Regenerators. Cooling towers. Furnaces. Exchanger fouling. Exchanger selection criteria. Various types of boilers.  
4. EMB424 Corrosion and its Prevention   E 3 0 3 5  
The course aims to teach metal oxidation mechanisms, the economic losses caused by corrosion, the electrochemical corrosion process, the types and mechanisms of corrosion, how reinforcement corrodes in concrete, how corrosion affects reinforcement life, and how the corrosion mechanism differs in environments with highly conductive and variable chemical compositions, such as seawater. It also aims to provide fundamental information on how to monitor the corrosion process, measurement methods, and interventions.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.  
Note: C: Compulsory Courses, E: Elective Courses, T: Theoretical Course Hour; P: Weekly Practice Course Hour, C: Course Credit, ECTS: European Credit Transfer System Credit of the Course.

Güncelleme 20.10.2025 15:43:01

 

Görüntülenme Sayısı: 1780