SYSTEM COURSE CATALOGUE FOR M.Sc. PROGRAMdepo.osmaniye.edu.tr/dosyalar/mmb/Dosyalar/MSc ECTS...
Transcript of SYSTEM COURSE CATALOGUE FOR M.Sc. PROGRAMdepo.osmaniye.edu.tr/dosyalar/mmb/Dosyalar/MSc ECTS...
OSMANİYE KORKUT ATA UNIVERSITY
INSTITUTE OF NATURAL AND APPLIED
SCIENCES
DEPARTMENT OF MECHANICAL
ENGINEERING
EUROPEAN CREDIT TRANSFER
SYSTEM COURSE CATALOGUE
FOR M.Sc. PROGRAM
OCTOBER 2017
TABLE OF CONTENTS
1. GENERAL INFORMATION .............................................................................. 2
1.1. Laboratories ................................................................................................... 3
1.3.1. Fluid Mechanics Laboratory ................................................................... 3
1.3.2. Manufacturing Laboratory ...................................................................... 3
1.3.3. Heat Laboratory ...................................................................................... 3
1.3.4. Control Laboratory .................................................................................. 4
1.3.5. Materials Laboratory ............................................................................... 4
1.3.6. Thermodynamics Laboratory .................................................................. 4
1.3.7. Powder Metallurgy Laboratory ............................................................... 4
1.3.8. Advanced Computation Laboratory ........................................................ 4
2. REGULATIONS AND ASSESMENTS ............................................................. 5
3. LIFE IN OKU ...................................................................................................... 5
4. CURRICULUM OF M.Sc. PROGRAM ............................................................. 6
4.1. Courses of M.Sc. Program ............................................................................ 7
5. COURSE CONTENTS OF M.Sc. PROGRAM .................................................. 8
6. INFORMATION FORMS OF M.Sc. PROGRAM ...........................................19
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DEPARTMENT OF MECHANICAL ENGINEERING
Karacaoglan Campus Fakıuşagı Neighborhood. Center/OSMANİYE
Phone: 0(328) 827 10 00
Fax: 0(328) 827 10 0
Web: http://www.mmb.osmaniye.edu.tr
DEPARTMENT
Chair of Department: Prof. Dr. Mustafa ÜBEYLİ
Phone 0(328) 827 10 00/3450
Fax: 0(328) 827 10 00
E-mail: [email protected]
Vice-Chair of Department: Assoc. Dr. Önder KAŞKA
Phone: 0(328) 827 10 00/3453
Fax: 0(328) 827 10 00
E-mail: [email protected]
ECTS COORDINATION
ECTS Coordinator: Assist. Prof. Dr. Mehmet Seha TATLIER
Phone: 0(328) 827 10 00/3457
Fax: 0(328) 827 10 00
E-mail: [email protected]
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1. GENERAL INFORMATION
Mechanical Engineering is one of the fundamental disciplines in engineering
which covers different and wide range of areas. In this respect, mechanical
engineering is a discipline which has one of the broadest working fields. With the
rapidly developing technology, new sub-branches and specific topics are emerging
in the field of mechanical engineering; there are many technical problems that need
to be researched and resolved. Therefore, there is a need for specialists (Professional
Engineers) with a master's degree specializing in a field in Mechanical Engineering
in order to solve problems in these sub-branches and special issues. The main
objective of the graduate program in Mechanical Engineering is to educate students
as highly specialized engineers and researchers with high knowledge and skills who
can solve current and future problems related to mechanical engineering by taking
the latest information in advanced technical and professional fields of mechanical
engineering. In this way, it is aimed to meet the needs of the industry and research
institutions for qualified and well-trained specialists.
Based on these requirements, Master of Science Program in Mechanical Engineering
was opened in 2012 within Osmaniye Korkut Ata University Institute of Natural and
Applied Sciences with thesis and without thesis.
Master of Science (MS) Degree in Mechanical Engineering consists of at least 7
courses, a seminar course, and a master thesis on the condition of 120 ECTS credits.
The Master's program without thesis is composed of at least ten courses not less than
60 ECTS credits and a term project.
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Master's Program courses in Mechanical Engineering have been constituted in order
to provide students with the basis for their research and ability to solve technical
problems. Two of the courses in the Master's Program with Thesis (Advanced
Engineering Mathematics and Scientific Research Methods and Publication Ethics)
are compulsory and the other five are technical selective. Seminar course is non-
credit and evaluated as successful or unsuccessful. The topic of the seminar is the
beginning and basis of the student's thesis work. The Master's Thesis includes the
theoretical and/or experimental work on a subject related to the fields of mechanical
engineering. Students must successfully complete the courses and seminar they have
taken at the end of the 4th semester.
1.1. Laboratories
1.3.1. Fluid Mechanics Laboratory
In Fluid Mechanics Laboratory, pressure losses due to the flow of fluids, hydraulic
system usage and pneumatic systems usage experiments are performed
1.3.2. Manufacturing Laboratory
At the Manufacturing Laboratory, both the undergraduate and graduate experiments
related to machining operations are performed. In this laboratory, there are hacksaw,
upright drill press and CNC milling machine.
1.3.3. Heat Laboratory
At Heat Laboratory efficiency calculations of heat wheel, efficiency calculations of
recovery systems with heat pumps, efficiency calculations water based heat
exchanger, efficiency calculations of heat exchangers with plates are performed.
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1.3.4. Control Laboratory
In Control Laboratory, the experiments related to electric machines, energy
measurement, power measurement and connecting counter and measurement
devices are performed.
1.3.5. Materials Laboratory
In materials laboratory, simple tension and compression, three points bending,
hardness, impact, metallography and heat treatment experiments are performed.
1.3.6. Thermodynamics Laboratory
In thermodynamics laboratory, heat recovery and various usages, efficiencies,
cooling effects and elements of cooling systems, natural and forced heat transfer
concepts are conveyed students via experiments.
1.3.7. Powder Metallurgy Laboratory
At the Powder Metallurgy Laboratory, both the undergraduate and graduate studies
are carried out on the production of metals and metal matrix composites. In this
laboratory, there are precision balance, hepa filter fume hood, mixer, attritor mill,
particle size analyzer, press, tube furnace and microwave sintering furnace devices.
1.3.8. Advanced Computation Laboratory
In Advanced Computation Laboratory; engineering computations are performed.
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2. REGULATIONS AND ASSESMENTS
Students can be found the regulations and assessments in Osmaniye
Korkut Ata University Rules and Regulations Governing Graduate
Studies:
http://documents.osmaniye.edu.tr/repository/Mevzuat/OK%C3%9C%20
%C3%96nlisans%20ve%20Lisans%20E%C4%9Fitim%20%C3%96%C
4%9Fretim%20Y%C3%B6netmeli%C4%9Fi.pdf
3. LIFE IN OKU
• How to arrive Osmaniye: http://erasmus.osmaniye.edu.tr/15795_erasmus-
deneyim-payla%C5%9F%C4%B1m%C4%B1.html
• Canteen and dining http://osmaniye.edu.tr/sayfa/52
• Accommodation and practical info:
http://erasmus.osmaniye.edu.tr/18861_foto-galeri.html
• For more information: http://intoffice.osmaniye.edu.tr/index.php
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4. CURRICULUM OF M.Sc. PROGRAM
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4.1. Courses of M.Sc. Program
Code Course Name C/E* T E C ECTS
MMB 501 Advanced Engineering Mathematics C 4 0 4 7
MMB 502 Scientific Research Methods and Publication Ethics C 3 0 3 6
MMB 503 Theoretical Design Studies E 3 0 3 6
MMB 504 Fuels and Combustion E 3 0 3 6
MMB 505 Experimental Design Studies E 3 0 3 6
MMB 507 Advanced Conduction Heat Transfer E 3 0 3 6
MMB 508 Advanced Convection Heat Transfer E 3 0 3 6
MMB 510 Advanced Radiation Heat Transfer E 3 0 3 6
MMB 512 Advanced Thermodynamics I E 3 0 3 6
MMB 513 Advanced Thermodynamics II E 3 0 3 6
MMB 516 Heating Systems E 3 0 3 6
MMB 518 Numerical Solutions in Heat Transfer E 3 0 3 6
MMB 520 Automotive Air-Conditioning Systems and Applications E 3 0 3 6
MMB 532 Powder Metallurgy E 3 0 3 6
MMB 533 Composite Materials E 3 0 3 6
MMB 535 Materials Characterization Techniques E 3 0 3 6
MMB 537 Oxidation and Corrosion of Metals E 3 0 3 6
MMB 538 Failure Analysis E 3 0 3 6
MMB 539 Computer Integrated Manufacturing E 3 0 3 6
MMB 540 Fracture Mechanics E 3 0 3 6
MMB 550 Software Applications in Mechanical Engineering E 3 0 3 6
MMB 551 Structural Dynamics E 3 0 3 6
MMB 552 Numerical Methods in Engineering E 3 0 3 6
MMB 554 Continuum Mechanics E 3 0 3 6
MMB 556 Elasticity Theory E 3 0 3 6
MMB 557 Fundamentals of Solid Mechanics E 3 0 3 6
MMB 559 Advanced Dynamics E 3 0 3 6
MMB 561 Plates and Shells E 3 0 3 6
MMB 563 Exergy and Entropy Analysis E 3 0 3 6
MMB 564 Energy Economics and Management E 3 0 3 6
MMB 565 Fossil Energy Resources E 3 0 3 6
MMB 566 Computational Fluid Dynamics E 3 0 3 6
MMB 567 Cogeneration Systems E 3 0 3 6
MMB 568 Engineering Data Processing Techniques E 3 0 6 6
MMB 570 Finite Volume Method E 3 0 3 6
MMB 571 Turbine Technologies E 3 0 3 6
MMB 572 Renewable Energy Sources E 3 0 3 6
MMB 573 Gas-Liquid Flows and Heat Transfer E 3 0 3 6
MMB 574 Computer Aided Analysis E 3 0 3 6
MMB 575 Fuel Cells and Applications E 3 0 3 6
MMB 576 Hydrogen Production Technologies E 3 0 3 6
MMB 591 Specialized Field Course C 4 0 0 5
MMB 592 Specialized Field Course C 4 0 0 5
MMB 598 Seminar C - - - 7
MMB 599 M.S Thesis C - - - 25
*C:Compulsory, E:Elective.
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5. COURSE CONTENTS OF M.Sc. PROGRAM
MMB 501 Advanced Engineering Mathematics
Elementary methods for solution of ordinary differential equations: linear
differential equations, linear differential equations with constant coefficients,
method of undetermined coefficients, Euler’s equations, reduction of order, variation
of parameters, simultaneous linear differential equations. Series solutions of
ordinary differential equations, method of Frobenius. Fourier series, double Fourier
series. Partial differential equations: wave equation, diffusion equation, Laplace’s
equation, Poisson’s equation, biharmonic equations. Boundary conditions.
Separation of variables. Orthogonal functions: Gamma, Bessel, Laguerre functions.
Legendre and Chebyshev polynomials. Complex variable theory. Complex variables
with analytic functions, line integrals of complex variable functions. The weights
(residual) calculation. Solution of Contour integrals by weight (residual) theory.
MMB 502 Scientific Research Methods and Publication Ethics
Science. Scientific research and scientific methods. Access to scientific knowledge:
use of library, academic surveying techniques. Reading scientific article. Methods
of scientific approach: quantitative, qualitative and mixed. Methods of scientific
research topic. Data collection, sampling and analysis methods. Validity and
reliability of knowledge. Academic writing rules. What is ethics? Ethics and Ethical
standards in science. Ethics in method and process. Ethics in subject and verity.
Research ethics. Publication ethics. Principles of scientific and publication ethics.
Citation. Case studies.
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MMB 503 Theoretical Design Studies
General principles of engineering design. Systems working principles. Physical and
mathematical analysis and application of engineering principles of machines,
equipments and processes. Stages of engineering design. Determining of possible
solutions for a given assignment, discussion and evaluation of these solutions.
Programming of all design stages. Computer aided drawing of the final solution.
MMB 504 Fuels and Combustion
Solid, liquid and gaseous fuels. Combustion systems, multi-element and variable
structure systems, thermodynamics, chemical reactions, chemical equilibrium,
combustion physics, kinetic and diffusion controlled combustion, diffusion flame,
pre-mixed gases and flame combustion, laminar flame.
MMB 505 Experimental Design Studies
Experiment planning. Definition of the problem. Problem solving techniques.
Experiment planning glossary. Controllable and uncontrollable dependent and
independent parameters. Experimental parameters, levels. Tools for finalizing
experiment planning, Determination of levels, factor combinations, selection of
design of experiment technique and experiments numbers. Error analysis in the
experiments, analysis of experimental data with various computer programs.
MMB 507 Advanced Conduction Heat Transfer
Relations, Boundary Conditions. With and without time-dependent solutions of heat
conduction problems. Solid, liquid and gas environments, heat conduction in
Cartesian, cylindrical and spherical coordinates, one, two and three-dimensional heat
conduction.
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MMB 508 Advanced Convection Heat Transfer
General and specific laws of convective heat transfer. And the formulation of
balance equations. Differential and integral equations for the boundary conditions.
Convective heat transfer in laminar and turbulent flow. Convective heat transfer with
phase change media, the similarity between heat and momentum transfer, heat
transfer in high-speed flows. Free convection boundary conditions. Analysis and
design of heat exchangers. Package type heat exchangers. In parallel, opposing, and
cross-flow heat transfer by convection.
MMB 510 Advanced Radiation Heat Transfer
Radiation heat transfer basic concepts. Fundamentals of statistical thermodynamics
and electromagnetic wave radiation heat transfer mechanism. Radiation properties
of real surfaces. Figure factors. Radiation heat transfer in dispersed homogeneously
gray surfaces. Radiation between surfaces such as mirrors, gas, radiation, exact and
approximate solution methods. Homogeneous radiation interaction with materials.
Interaction of radiation interfaces. Black body radiation. Real-surface radiation.
Radiative heat transfer, radiation-absorbing surfaces.
MMB 512 Advanced Thermodynamics I
Understanding of second law of thermodynamics, Enhanced power cycles,
Enhanced Refrigeration cycles, Thermodynamic property relations, Gas mixtures,
Gas-Vapor mixtures and air-conditioning, Chemical Reactions, Combustion and
fuels, Chemical and phase equilibrium Thermodynamics of high speed gas flow.
MMB 513 Advanced Thermodynamics II
The first and second laws of thermodynamics combined. Second law analysis of
engineering systems. Kinetic theory of gases. Constitutive equations, Property
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relations and their applications to compressible systems. Surface phenomena, Elastic
solid, Non-reactive mixtures, Chemical reactions, and thermodynamic stability.
Exergy generalized. Multiphase systems. The third law of thermodynamics.
Irreversible thermodynamics.
MMB 516 Heating Systems
Various heating systems and their comparison. Steam boilers. Superheated and hot
water boilers. Diathermic oil boilers. Air heaters. Fuel tanks and burners. Expansion
tanks and balance systems. Hot water systems. Circulation pumps. Links used in
heating systems. Removers and steam separators. Industrial furnaces and their
design. Several chimney systems. Stack emissions and methods of prevention of
harmful emissions. Criteria for waste heat utilization. Rotary regenerators. Cross-
flow plate heat exchangers. Evaluation of heat exchangers. Pipes and channels
according to various criteria dimensioning economically.
MMB 518 Numerical Solutions in Heat Transfer
Differential equations of heat transfer. Boundary conditions. Regular boundaries and
coordinate transformation. Finite difference method. Importance of grid spacing.
Variable grid spacing. Formulation of different boundary conditions. Methods for
the solution of algebraic equations. Methods for the solution of parabolic and elliptic
differential equations. Applications for different problems.
MMB 520 Automotive Air-Conditioning Systems and Applications
Used in automotive air conditioning systems. Heat loss and gain calculation. System
elements, selection criteria, the principles of the system and installation. Startup
automotive air conditioners, air conditioning, automatic control systems, test
procedures, specifications, evaluation and reporting of test results.
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MMB 532 Powder Metallurgy
Metallic powder production techniques: Atomization, chemical, electrolytic and
grinding techniques. Characterization of metallic powders. Compacting metallic
powders: briquetting, pressing, rolling, extrusion, hot and cold isostatic pressing,
powder injection molding. Sintering: Steps, furnaces and gases. Full densification.
Mechanical properties of PM materials. Powder systems and applications.
MMB 533 Composite Materials
Principles of composite materials. Fiber reinforced composites. Particulate
reinforced composites. Laminated composites. Fiber reinforcements. Fiber types.
Particulate reinforcements. Properties of interface. Polymers. Thermoplastics.
Thermosets and elastomers. Manufacturing methods of composites: Polymer matrix
composites, metal matrix composites, ceramic matrix composites. Mechanical
properties of composites. Application fields of composites.
MMB 535 Materials Characterization Techniques
Basic principles of materials characterization, physical properties and experimental
methods, elemental and chemical analysis, X-rays, spectroscopy and spectrometry
techniques, magnetic measurements, optical and electron microscopes, termal
characterization methods, powder size and surface analysis techniques, mechanical
testing methods.
MMB 537 Oxidation and Corrosion of Metals
Electrochemical principles of corrosion; Thermodynamic approach on corrosion
tendency, polarization and its application on corrosion rates. Passivity. Corrosion
types. Corrosion in various environments. Prevention methods of corrosion: design,
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material selection, surface coating, improving environment, anodic and cathodic
protection. Oxidation of metals.
MMB 538 Failure Analysis
Aims of failure analysis. General procedure of failure investigation: Getting
previous data, preinvestigation, nondestructive testing. Examining macro and micro
fracture surfaces. Metallographic and fractographic analyses, chemical analyses.
Determining fracture type. Application of fracture mechanics. Investigation on
various fracture types on components.
MMB 539 Computer Integrated Manufacturing
Information-based technologies in manufacturing. Examining technical
specification of part and computer aided design. Making integrated product/process.
Automation and control of manufacturing methods: Programmable logic controllers
(PLCs), structure of computer numerical control (CNC) and programming.
Industrial robotic. Making free shaped solid (laminated production, rapid
prototyping). Information based manufacturing. Computer aided process planning.
Internet aided manufacturing. Management of product data. Management of recently
developed manufacturing technologies.
MMB 540 Fracture Mechanics
Griffith theory of crack, crack stress analysis, design philosophy, the relationship
between energy and stress approximation methods. Presence of the crack tip plastic
zone size. Plane stress overstretching transition. The plane-strain fracture toughness
tests, engineering materials, fracture toughness, crack tip toughness determination
of the method of unfolding. J-integral method and the determination of fracture
toughness of elastic-plastic behavior, disclosure and. Other methods of breaking.
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Impact energy-fracture toughness relationship. Fracture toughness of the micro-
structure relationships. Breaking effect of environmental conditions. Fracture
mechanics testing methods applied. Material life and the crack length calculation
methods. Strain-controlled fatigue, strain-controlled fatigue, notched elements,
fatigue life prediction, fatigue, corrosion, stress corrosion.
MMB 550 Software Applications in Mechanical Engineering
MATHCAD and presentation programs using symbolic algebra package
MATHEMATICA. With the help of these programs in mechanical engineering
solutions for a variety of problems (numeric and symbolic operations, vector and
matrix calculations, derivatives, integrals, limits and applications, graphics,
drawings, equations, area and volume calculations, arrays, procedures, statistical
calculations).
MMB 551 Structural Dynamics
Single degree of freedom systems. Permanent and temporary behavior. Multi degree
of freedom systems. Mass and stiffness matrices. Free and forced vibration. Wave
propagation in building systems.
MMB 552 Numerical Methods in Engineering
Finding roots of functions. Solution of linear systems of algebraic equations.
Eigenvalues and Eigenvectors. Interpolation and curve fitting. Numerical integration
methods. Ordinary differential equations, initial and boundary value problems.
Ordinary differential equation systems. Partial differential equations (elliptic,
hyperbolic, parabolic).
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MMB 554 Continuum Mechanics
Examination of stress and strain at a point. To obtain the basic equations of a
continuous medium. The deformation gradients and tensors. Transformation of
strain and rotations. Constitutive laws and relations for solids and fluids. Finite
deformation. Elastic and hyperelastic materials.
MMB 556 Elasticity Theory
Mathematical Foundations. Stress Analysis. Analysis of Strain. Conservation Laws.
Linear Elasticity. Constitutive Equations. Generalized Hooke's Law. Basic
Equations of Elasticity Theory. Stress Problems. Displacement Problem. Conditions
of Eligibility. General Theory of Plane Elasticity. Plane Stress (Thin Plate Problem).
Plane Strain (Long Cylinder Problem). Solution Vertical Axes. Stress Functions.
Airy Stress Function. Boundary Conditions. Biharmonic functions. Examples.
Solution by Fourier Series. Examples. Solutions in Polar Coordinates. Examples.
Three-Dimensional Elasticity. Saint-Venant Torsion and Bending Theory. Galerkin
vector. Papkovich-Neuber Solutions.
MMB 557 Fundamentals of Solid Mechanics
Introduction to Linear continuous media. Stress-strain tensors. Conservation laws.
Constitutive equations. Materials elastic, viscoelastic, and viscoplastic behavior.
Variational account login and energy methods. Plasticity. Finite deformations.
MMB 559 Advanced Dynamics
Hamilton's principle. Generalized variables. Lagrange's equations. Rigid body
dynamics. Euler angles. Gyroscopic systems under the influence. Three-dimensional
dynamics of rigid bodies. Relative velocity and acceleration relations. Element that
has characteristics of time varying and non-linear vibration of some systems.
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MMB 561 Plates and Shells
Classical plate theory, classification, boundary conditions, application of Cartesian
and polar coordinates. Approximate methods. Energy methods. Bending theory of
shells. Cylindrical, spherical and rotational shells. With the application of numerical
methods.
MMB 563 Exergy and Entropy Analysis
The basic thermodynamic concepts and laws. Exergy and Energy Definition,
Operability and exergy: historical development. Exergy Balance and Exergy Losses,
Thermal Systems Exergy Efficiency, Exergy Analysis of the Basic Thermodynamic
Applications, Exergy Account, Open Systems, Exergy Account, Physical Exergy
Account, Chemical Exergy Account, Typical Thermal Systems Exergy Analysis of
Thermal Esansorlerinin Exergy Analysis, Vapor Compression Refrigeration
Systems and Heat Pumps Exergy Analysis of Thermal Converters of Exergy
Analysis, the Combined Processes of Exergy Analysis, Solar Collectors, Exergy
Analysis. Adiabatic systems. Stable flow of the processes of usage gives (exergy).
Stable and non-stream usage gives and exergy. Irreversible systems and processes
characteristic features.
MMB 564 Energy Economics and Management
General introduction and identification of the energy economy methods, industry,
energy economy, applications, industrial plants and enterprises, energy-saving
designs, sample projects on general applications. The energy of an economic,
technological, political, and environmental dimensions of the investigation of the
energy systems, energy, and economic growth, energy demand and energy
conservation, the international energy markets, a national energy policy, energy
management, energy saving, promotion of methods of economic analysis methods.
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MMB 565 Fossil Energy Resources
Fossil energy sources, definition, classification and history of burning Fossil fuels
to power plants, comparison of the operation. Fossil fuel reserves in the world and
Turkey. Fossil resources, environmental and economic point of comparison.
MMB 566 Computational Fluid Dynamics
Computational fluid dynamics in the context of the entry. Fundamental equations of
fluid dynamics. Investigation of flow characteristics. Investigation of the fluid
motion. Boundary conditions. Computational fluid dynamics technology. Finite
difference and finite volume method. Other methods. Solution algorithms.
Turbulence and modelling. Combustion modeling.
MMB 567 Cogeneration Systems
Definition of cogeneration. Cogeneration systems. Cogeneration systems used in the
thermodynamic cycles. Industrial waste heat recovery. Cogeneration systems,
energy-exergy analysis. Preparation the feasibility in cogeneration systems.
MMB 568 Engineering Data Processing Techniques
Basic information of data processing, importance of data bases in engineering and
business life, data processing and analysis with the relevant package of programs
and engineering-related applications.
MMB 570 Finite Volume Method
Numerical solution of Hyperbolic functions in format of the Lax-friedrichs method.
Godunov method and the riemann solutions. The convergence, stability and
accuracy. Compressible and incompressible flows, shock and spread. Balance and
response flow equations.
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MMB 571 Turbine Technologies
Definition and classification of the turbines, Efficiency/thermodynamic analyses of
different type turbines for the necessary basic knowledge, methods and comparisons.
Projects on the evaluation of applications of turbines,
MMB 572 Renewable Energy Sources
Renewable forms of energy affordability, availability, countries on the basis of the
use of solar energy, wind energy, small hydro-turbines, biomass, geothermal energy,
wave energy, flow, tidal power, such as types with other energy range of comparison.
Renewable energies, resources, environment and economy with basic information
about, solar, geothermal, wind, biomass, wave, OTEC, hydrogen, wind and nuclear
energy.
MMB 573 Gas-Liquid Flows and Heat Transfer
The main models of gas-liquid flows. Various forms of gas-liquid flows. State of the
liquid film flow modeling. Examples of empirical approach. Examination of boiling
and condensation. Boiling and condensation of multi-component systems. Over-
cooled boiling. Filled and cooling towers, pressure drop, heat and mass transfer
analysis. Desorber absorber and heat and mass transfer.
MMB 574 Computer Aided Analysis
Introduction to ANSYS. Direct and Solid modeling. Solution of mechanical
engineering problems with ANSYS (static and buckling solutions of beams and
plates, static solution of plane and space frame systems). Thermal stress and non-
linear examples. Ansys applications about structural analysis. Ansys applications
about thermo-mechanical analysis. Ansys applications about free vibration and
forced vibration. Solution of contact problem with Ansys.
19
MMB 575 Fuel Cells and Applications
Definitions, historical development. Emissions; Overview of Fuel Cell Systems;
Alkaline Fuel Cells, Molten Carbonate Fuel Cells, Solid Oxide Fuel Cells and Solid
Polymer Fuel Cells Terms and Principles, Typical Cell Materials, Cell
Configurations, Applications and Economics; Principles of Fuel Cell
Electrochemistry. Criteria of chemical equilibrium, Equilibrium constants.
Chemical kinetics: reaction rates, Arrhenius equation. Activation energy. Middle
and High Heat Fuel Cell. Fuel Cell Applications.
MMB 576 Hydrogen Production Technologies
Importance for energy conversion systems of hydrogen as an energy carrier and the
technical features. Production of hydrogen by electrolysis of water. Electrolysis and
types. Electrolyzer performance model. Generating electricity from hydrogen and
fuel cells. Examples of renewable energy sources for hydrogen production:
Photovoltaic solar panels, wind turbine generators, water powered electro-
mechanical systems. Renewable energy-hydrogen systems analysis and modeling.
6. INFORMATION FORMS OF M.Sc. PROGRAM
Osmaniye Korkut Ata University
MMB501 Advanced Engineering Mathematics
Credit ECTS
4 4 7Advanced Engineering Mathematics
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
S.Ş. Bayın. Fen ve Mühendislik Bilimlerinde Matematik Yöntemler, Metu Press, Ankara.,Peter V. O'Neil,. Advanced Engineering Mathematics, Thomson Book Cole.,E.Kreyzig,. Advanced Engineering Mathematics, McGraw-Hill Book Co.
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
7030
Semester Course Code Course Name L+P
1 MMB501
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:ZorunluGoals:The target of this course is to teach advanced mathematical methods that used in engineering mathematic.Teaching Methods and Techniques:Elementary methods for solution of ordinary differential equations: linear differential equations, linear differential equations with constant coefficients, method of undeterminedcoefficients, Euler’s equations, reduction of order, variation of parameters, simultaneous linear differential equations. Series solutions of ordinary differential equations, method ofFrobenius. Fourier series, double Fourier series. Partial differential equations: wave equation, diffusion equation, Laplace’s equation, Poisson’s equation, biharmonic equations.Boundary conditions. Separation of variables. Orthogonal functions: Gamma, Bessel, Laguerre functions. Legendre and Chebyshev polynomials. Complex variable theory. Complexvariables with analytic functions. , line integrals of complex variable functions. The weights (residual) calculation. Solution of Countour integrals by weight (residual) theory.Prerequisites:
Course Coordinator:
Instructors:Asist Prof. Durmuş YARIMPABUÇAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 General information about the differential equations. The origin of differential equations.2 Methods for the solution of ordinary differential equations. Linear ordinary differential equations3 Linear differential equations with constant coefficients, method of undetermined coefficients, Euler's equation.4 The method of reduction of order, variation of parameters method, simultaneous linear differential equations.5 Series solutions of ordinary differential equations.6 Method of Frobenius7 method of Frobenius8 Fourier series, double Fourier series.9 Mid term10 Partial differential equations: wave equation, diffusion equation, Laplace’s equation, Poisson’s equation, biharmonic equations. Boundary conditions. Separation of variables.11 Separation of variables.12 Orthogonal functions: Gamma, Bessel, Laguerre functions. Legendre and Chebyshev polynomials.13 Complex variable theory. Complex variables with analytic functions.14 Line integrals of complex variable functions. The weights (residual) calculation. Solution of Countour integrals by weight (residual) theory.
Course Learning Outcomes
No Learning OutcomesC01 (S)He recognizes elementary methods for solution of ordinary differential equations.C02 (S)He finds series solutions of ordinary differential equationsC03 (S)He explains the Fourier series, double Fourier series.C04 (S)He distinguish partial differential equations (wave equation, diffusion equation, Laplace’s equation, Poisson’s equation, biharmonic equations).C05 (S)He distinguish boundary conditions.C06 (S)He solves the partial differential equation using the method of separation of variablesC07 (S)He recognizes orthogonal functions: Gamma, Bessel, Laguerre functions. Legendre and Chebyshev polynomials.C08 (S)He finds line integrals of complex variable functionsC09 (S)He finds solution of Countour integrals by weight (residual) theory.
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %30
Quizzes 0 %0
Assignment 5 %20
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %50
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 16 4 64
Hours for off-the-c.r.stud 16 4 64
Assignments 5 4 20
Presentation 0 0 0
Mid-terms 1 30 30
Practice 0 0 0
Laboratory 0 0 0
Project 1 40 40
Final examination 0 0 0
218 Total Work Load
ECTS Credit of the Course 7
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 3 1 3 3 4 3 2 3 2 1 2 4 3
C01 3 1 3 3 4 3 2 3 2 1 2 4 3
C02 3 1 3 3 4 3 2 3 2 1 2 4 3
C03 3 1 3 3 4 3 2 3 2 1 2 4 3
C04 3 1 3 3 4 3 2 3 2 1 2 4 3
C05 3 1 3 3 4 3 2 3 2 1 2 4 3
C06 3 1 3 3 4 3 2 3 2 1 2 4 3
C07 3 1 3 3 4 3 2 3 2 1 2 4 3
C08 3 1 3 3 4 3 2 3 2 1 2 4 3
C09 3 1 3 3 4 3 2 3 2 1 2 4 3
Osmaniye Korkut Ata University
MMB502 Bilimsel Araştırma Yöntemleri ve Yayın Etiği
Credit ECTS
3 3 6Bilimsel Araştırma Yöntemleri ve Yayın Etiği
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Instructor notes
Ders NotuBilimsel Makale HazırlamaAra sınav
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
10401010
Semester Course Code Course Name L+P
2 MMB502
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:ZorunluGoals:To be able to learn and apply scientific research methods in accordance with ethical standards. To increase the quality of students' theses and scientific articles in scientific and ethicalterms.Teaching Methods and Techniques:Science, scientific research and scientific methods. Scientific knowledge access: library use, academic search techniques. Reading scientific articles. Research approach methods:quantitative, qualitative and mixed. Research topic determination methods. Data collection, sampling and analysis methods. The validity and reliability of information. Academicwriting rules. What is ethics? Ethics in science and ethical standards. Method and ethics in the process. Subject and ethics in findings. Research ethics. Publishing ethics. Scientific andpublishing ethical principles. Adding of references . Sample applications.Prerequisites:
Course Coordinator:
Instructors:
Assistants:
Education Science Health Field
: : : :
1010
10
Course Content
Week Topics Study Materials Materials1 Science, scientific research and scientific methods.
Course Learning Outcomes
No Learning OutcomesC01 Science RecognitionC02 To make scientific researchC03 Learning and compliance with ethical standardsC04 To be able to prepare effective scientific studyC05 Adding and editing references
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %40
Quizzes 0 %0
Assignment 0 %0
Attendance 0 %0
Practice 1 %60
Project 0 %0
Final examination 0 %0
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 3 42
Assignments 0 0 0
Presentation 0 0 0
Mid-terms 1 30 30
Practice 1 60 60
Laboratory 0 0 0
Project 0 0 0
Final examination 0 0 0
174 Total Work Load
ECTS Credit of the Course 6
Osmaniye Korkut Ata University
MMB 503 Theoretical Design Studies
Credit ECTS
3 3 6Theoretical Design Studies
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
203050
Semester Course Code Course Name L+P
2 MMB 503
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:To learn the general principles of engineering design, implementation and results of the problems to be skilled in investigationTeaching Methods and Techniques:
Prerequisites:
Course Coordinator:
Instructors:
Assistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 The creation of the basic principles of engineering design2 The creation of the basic principles of engineering design3 The creation of the basic principles of engineering design4 The creation of a mathematical model to design problems5 The creation of a mathematical model to design problems6 The creation of a mathematical model to design problems7 Programming of the mathematical model8 the creation of various design stages9 Example of design problems solution by various methods10 Example of design problems solution by various methods11 Example of design problems solution by various methods12 Drawing of the project with computer aided program13 Drawing of the project with computer aided program14 Drawing of the project with computer aided program
Course Learning Outcomes
No Learning OutcomesC01 The ability to create mathematical models in engineering design problemsC02 Solution prepared in accordance with the principles of design and evaluation of various methods of mathematical model
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %20
Quizzes 0 %0
Assignment 1 %20
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 5 70
Assignments 1 20 20
Presentation 0 0 0
Mid-terms 1 20 20
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 20 20
172 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
C01 4 3 5 5 1 2 3 3 3 4 4 1 1
Osmaniye Korkut Ata University
MMB507 Advanced Heat Conduction
Credit ECTS
3 3 6Advanced Heat Conduction
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Introduction to Heat Transfer I: Heat Conduction, Sadık Kakaç,Principles of the Heat Conduction, Macit Çiğdemoğlu,Heat Conduction, Sadık Kakaç, Yaman Yener,Heat Conduction, M.Necati Özışık
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
306010
Semester Course Code Course Name L+P
1 MMB507
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:Conduction heat transfer to and knowledge of advanced topics related to the analysis of problems and generating solutionsTeaching Methods and Techniques:Relations, Boundary Conditions. With and without time-dependent solutions of heat conduction problems. Solid, liquid and gas environments, heat conduction in cartesian, cylindricaland spherical coordinates, one, two and three-dimensional heat conduction.Prerequisites:
Course Coordinator:
Instructors:Asist Prof.Dr. Şaban ÜNALAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Foundation of Heat Transfer2 Introductory remarks3 General heat conduction equations, derivation of heat conduction equation4 Steady flow of heat transfer in one dimension5 Problem solutions6 Initial and boundary conditions to solve heat conduction equation7 Internal heat generation8 Problem solutions9 Extended surfaces-Fins10 Differential equation for fins11 Analytical and numerical solutions of differential equations of fins12 Problem solutions13 Steady two dimensional heat conduction14 Time-dependent heat conduction in solids
Course Learning Outcomes
No Learning OutcomesC01 Having knowledge about the basic concepts of heat conductionC02 Bring the general differential equation of heat conduction in Cartesian coordinates. To understand the meaning of each term. Differential equation of heat conduction in cylindrical and spherical coordinates to be informed about.C03 Initial and boundary conditions for the solution of differential equations and use them. Knowledge of heat transfer fins and fin surfaces to solve problems.C04 Having knowledge about heat transfer fins and fin surfaces to solve problemsC05 Numerical methods to solve differential equations of heat conduction.C06 As a result of heat conduction differential equations solved by numerical methods to compare the results obtained by analytical methods.
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %80
Quizzes 0 %0
Assignment 4 %20
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%160 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 16 3 48
Hours for off-the-c.r.stud 14 5 70
Assignments 4 15 60
Presentation 0 0 0
Mid-terms 0 0 0
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 2 2
180 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 5 3 3 3 4 3 4 5 3 4 4 5 5
C01 5 3 3 3 4 3 4 5 3 4 4 5 5
C02 5 3 3 3 4 3 4 5 3 4 4 5 5
C03 5 3 3 3 4 3 4 5 3 4 4 5 5
C04 5 3 3 3 4 3 4 5 3 4 4 5 5
C05 5 3 3 3 4 3 4 5 3 4 4 5 5
C06 5 3 3 3 4 3 4 5 3 4 4 5 5
Osmaniye Korkut Ata University
MMB508 Advanced Convection Heat Transfer
Credit ECTS
3 3 6Advanced Convection Heat Transfer
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
405010
Semester Course Code Course Name L+P
1 MMB508
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:The most important mechanism of heat transfer, convection, to examine the issue in detail.Teaching Methods and Techniques:General and specific laws of convective heat transfer.Convective heat transfer in laminar and turbulent flow.Prerequisites:
Course Coordinator:
Instructors:Asist Prof.Dr. Ertuğrul CihanAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 General and specific laws of heat transfer by convection2 Equilibrium equations and formulations.3 Differential and integral equations for the boundary conditions4 Convective heat transfer in laminar and turbulent flow.5 Convective heat transfer without phase change6 The similarity between heat and momentum7 heat transfer in high-speed flows8 Free convection boundary conditions.9 Analysis and design of heat exchangers.10 Plate type heat exchangers11 Parallel and cross-flow heat transfer.12 Mathematical modeling of heat transfer problems13 Mathematical models solved with the program package14 Mathematical models solved with the program package
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %70
Quizzes 0 %0
Assignment 2 %30
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 0 %0
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 0 0 0
Assignments 2 30 60
Presentation 0 0 0
Mid-terms 1 30 30
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 40 40
172 Total Work Load
ECTS Credit of the Course 6
Osmaniye Korkut Ata University
MMB512 Advanced Thermodynamics I
Credit ECTS
3 3 6Advanced Thermodynamics I
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
157015
Semester Course Code Course Name L+P
1 MMB512
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:Aim of the course is to intensify knowledge of thermodynamics learned during under-graduate program and teaching the some new thermodynamic subjects which student did nottake in under-graduate program.Teaching Methods and Techniques:Understanding of second law of thermodynamics ,Enhanced power cycles, Enhanced Refrigeration cycles, Thermodynamic property relations, Gas mixtures, Gas-Vapor mixtures andair-conditioning, Chemical Reactions , Combustion and fuels, Chemical and phase equilibrium Thermodynamics of high speed gas flow.Prerequisites:
Course Coordinator:
Instructors:
Assistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Review of first law and second law analysis basics2 Review of power cycle basics and introduction to enehanced power cycles3 Enhanced power cycles4 Enhanced refrigeration cycles5 Termodimak property relations6 Thermodynamic property relation7 Gas Mixtures8 Gas- Vapour mixtures and Air-conditioning9 Gas- Vapour mixtures and Air-conditioning10 Chemical Reactions,combustion11 Cehemical reactions, Combustion12 Chemical and Phase Equilibrium13 Thermodynamics of high-speed gas flow14 Thermodynamics of high-speed gas flow
Course Learning Outcomes
No Learning OutcomesC01 Understanding of principles of enhanced power cycles and ability to make first law analysisC02 Understanding of principles of enhanced refrigeration cycles and ability to make first law analysisC03 Knowledge of developing some fundemental relations between commonly encountered thermodynamic properties and express the properties that cannot be measured directly in terms of easily measureable propertiesC04 Knowlege of devoloping rules for determining mixture properties from a knowledge of mixture composition to be able to make energy analysis of air conditioning systemsC05 Knowledge of fixing chemical reaction and applying energy balances to reacting systemsC06 Knowledge of high speed gas flow thermodynamics relations
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %20
Quizzes 0 %0
Assignment 5 %40
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 0 %0
%60 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 16 3 48
Hours for off-the-c.r.stud 10 5 50
Assignments 5 8 40
Presentation 0 0 0
Mid-terms 1 10 10
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 22 22
170 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 4 3 3 2 3 3 4 5 5 4 5 4 4
C01 4 3 3 2 3 3 4 5 5 4 5 4 4
C02 4 3 3 2 3 3 4 5 5 4 5 4 4
C03 4 3 3 2 3 3 4 5 5 4 5 4 4
C04 4 3 3 2 3 3 4 5 5 4 5 4 4
C05 4 3 3 2 3 3 4 5 5 4 5 4 4
C06 4 3 3 2 3 3 4 5 5 4 5 4 4
Osmaniye Korkut Ata University
MMB 513 Advanced Thermodynamics II
Credit ECTS
3 3 6Advanced Thermodynamics II
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Advanced Thermodynamics For Engineers Kenneth WARK,Mc-Graw Hill
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
2030
Semester Course Code Course Name L+P
2 MMB 513
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:To give kowledge about subjects that students can need during their academic works,such as theory and experimental correlations for the properties of simple compressiblesubstances,multiphase multiş component systems,reacting systems,chemical exergy,exergy of cyclesTeaching Methods and Techniques:
Prerequisites:
Course Coordinator:
Instructors:
Assistants:
Education Science Health Field
: : : : 50
Course Content
Week Topics Study Materials Materials1 Equations of State2 Thermodynamics Property Relations3 Thermodynamic property relations4 Thermodynamics property relations5 The Third law of Thermodynamics6 Thermodynamic Properties of Homogenous Mixtures7 Thermodynamic Properties Of Homogenous Mixtures8 Multiphase-multicomponent systems9 Multiphase-Multicomponent systems10 Chemical Reactions11 Chemical Reactions12 Chemical Exergy13 Chemical Exergy of Fuels14 A stastical wiewpoint of Entropy
Course Learning Outcomes
No Learning OutcomesC01 knowledge of theory and experimental correlations for the important properties of simple compressible substancesC02 to be able to make exergy analysis of the cyclesC03 Having knowledge of thermodynamics of multi component-single phase and multi component-multiphase systemsC04 Having knowledge of reacting systems and chemical exergyC05 To cover the third law of the thermodynamics and its applications
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 0 %0
Quizzes 0 %0
Assignment 10 %100
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%160 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 5 70
Assignments 10 5 50
Presentation 0 0 0
Mid-terms 0 0 0
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 10 10
172 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 4 2 3 3 2 3 5 4 3 3 3 2
C01 4 2 4 3 3 2 3 5 4 3 3 3 2
C02 4 2 4 3 3 2 3 5 4 3 3 3 2
C03 4 2 4 3 3 2 3 5 4 3 3 3 2
C04 4 2 4 3 3 2 3 5 4 3 3 3 2
C05 4 2 4 3 3 2 3 5 4 3 3 3 2
Osmaniye Korkut Ata University
MMB514 Special Topics in Refrigeration and Air Conditioning
Credit ECTS
3 3 6Special Topics in Refrigeration and Air Conditioning
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Lecture notes are prepared.Different papersÇeşitli yayınlarDers notu içindeDers notu içinde
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
107020
Semester Course Code Course Name L+P
1 MMB514
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:The purpose of this lecture is to give informations about the speziel topics of refrigeration and air conditioning. As speziel topics in refrigeration are the invers Joule-Braton cycle, ORCwith inverse Rankine cycle using exhaust gas and supercritical Rankine cycle with invers Rankine cycle considered.As speziel topic of air conditioning is heating and cooling using VRVinvestigated.Teaching Methods and Techniques:Invers Joule-Brayton cycle. ORC and invers Rankine cycle. VRV systems.Prerequisites:
Course Coordinator:
Instructors:Prof.Dr. Tuncay YILMAZAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Çeşitli yayınlar Çeşitli yayınlarSoğutmaya giriş2 Çeşitli yayınlar Çeşitli yayınlarTers Joule-Brayton çevrimi3 Çeşitli yayınlar Çeşitli yayınlarTers Joule-Brayton çevriminin tek ve iki kademeli modelinin yapılması4 Çeşitli yayınlar Çeşitli yayınlarTers Joule-Brayton çevriminin hesaplanması.5 Çeşitli yayınlar Çeşitli yayınlarEksoz gazları kullanarak ORC ve ters Rankine çevrimi.6 Çeşitli yayınlar Çeşitli yayınlarORC ve ters Rankine çevriminin modellenmesi7 Çeşitli yayınlar Çeşitli yayınlarORC v e ters Rankine çevriminin hesaplanması.8 Çeşitli yayınlar Çeşitli yayınlarSüperkritik ORC ve ters Rankie çevrimi9 Çeşitli yayınlar Çeşitli yayınlarSüperkritik ORC ve ters Rankine çevriminin modellenmesi10 Çeşitli yayınlar Çeşitli yayınlarSüperkritik ORC ve ters Rankine çevriminin hesaplanması11 Çeşitli yayınlar Çeşitli yayınlarİklimlendirmeye giriş12 Çeşitli yayınlar Çeşitli yayınlarNormal VRV sistemleri13 Çeşitli yayınlar Çeşitli yayınlarİleri VRV sistemleri14 Çeşitli yayınlar Çeşitli yayınlarVRV sistemlerinin modellenmesi ve hesaplanması.
Course Learning Outcomes
No Learning OutcomesC01 Learning of different advansed refrigeration cycles.C02 Getting the skill of modelling of different refrigerating cycles.C03 Learning of calculation of different refrigeration cycles using EES program.C04 Understanding and getting the skill of calculation of VRV systems.
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %30
Quizzes 0 %0
Assignment 1 %20
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 0 %50
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 4 56
Assignments 1 20 20
Presentation 0 0 0
Mid-terms 1 20 20
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 20 20
158 Total Work Load
ECTS Credit of the Course 5
Osmaniye Korkut Ata University
MMB 518 Numerical Solutions in Heat Transfer
Credit ECTS
3 3 6Numerical Solutions in Heat Transfer
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
T. Yılmaz,Numerical Heat Transfer,Ç.Ü. Ders Notu.T. YILMAZ, Numerical Heat Transfer, Ç.Ü. Ders notları.,W.J.Minkowycz, E.M. Sparrow, J. Y. Murthy, Handbook of Numerical Heat Transfer, Wiley, 2006.T. Yılmaz,Numerical Heat Transfer,Ç.Ü. Ders Notu.DökümandaDökümanda
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
603010
Semester Course Code Course Name L+P
2 MMB 518
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:To give to the students the necessary knowledges for the numerical solution of the parabolic and elliptic diferantial equations and by preparation of programs to intensify theknowledges.Teaching Methods and Techniques:Diferantial equations of heat transfer. Boundary conditions.Irregular boundaries and coordinate transformation. Finite difference method. Importance of grid spacing. Variable gridspacing. Formulation of different boundary conditions. Methods for the solution of algebraic equations. Methods for the solution of parabolic and elliptic differantial equations.Applications for different problems.Prerequisites:
Course Coordinator:
Instructors:Prof.Dr. Tuncay YILMAZAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Explanation of finite differences.2 Derivation of finite differences.3 Explanation of explit and implicit methods.4 Application of finite difference method to Fourier differantial equation.5 Error analysis of finite differences.6 Analysis of equal and variable step sizes.7 Solution methods of algebraic equations.8 Formulation of different boundary conditions.9 Irregular boundaries.10 Coordinate transformation.11 Elliptic diferantial equations.12 Alternative direction method.13 Parabolic diferantial equation applicatiıon.14 Elliptic differantial equation application.
Course Learning Outcomes
No Learning OutcomesC01 To learn finite difference method.C02 To learn solution of algebraic equations.C03 The ability of the formulation of different boundary conditions.C04 Modelling a heat transfer problem and to solve it numerically.
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %20
Quizzes 0 %0
Assignment 3 %20
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 0 %0
%40 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 4 56
Assignments 3 12 36
Presentation 0 0 0
Mid-terms 1 20 20
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 20 20
174 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 4 2 1 5 5 2 3 4 1 1 2 5 2
C01 4 2 1 5 5 2 3 4 1 1 2 5 2
C02 4 2 1 5 5 2 3 4 1 1 2 5 2
C03 4 2 1 5 5 2 3 4 1 1 2 5 2
C04 4 2 1 5 5 2 3 4 1 1 2 5 2
Osmaniye Korkut Ata University
MMB 520 Automotive Air-Conditioning Systems and Applications
Credit ECTS
3 3 6Automotive Air-Conditioning Systems and Applications
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Lecture notes
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
306010
Semester Course Code Course Name L+P
2 MMB 520
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:To have detailed information about the used automotive air conditioners and to make the necessary calculations and analysisTeaching Methods and Techniques:Used in automotive air conditioning systems. Heat loss and gain calculation. System elements, selection criteria, the principles of the system and installation. Startup automotive airconditioners, air conditioning, automatic control systems, test procedures, specifications, evaluation and reporting of test results.Prerequisites:
Course Coordinator:
Instructors:Asist Prof.Dr. Şaban ÜNALAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Introduction and Fundamental Concepts2 Introduction and Fundamental Concepts3 Refrigeration Cycles4 Thermodynamics of Vapor Compression Refrigeration Cycles5 Thermodynamics of Vapor Compression Refrigeration Cycles6 Cooling Gain Calculation7 Cooling Device and Equipment8 Automobile Air Conditioning Systems9 Bus Air Conditioning Systems10 Frigorific Vehicle Air Conditioning Systems11 Automatic Control Systems12 Testing of Bus Air Conditioners13 Evaluation of Test Results14 Fault Diagnosis in Automotive Air Conditioners
Course Learning Outcomes
No Learning OutcomesC01 To be used in the general knowledge of automotive air conditioners.C02 Heat gain calculation of the vehicle to be make.C03 To have detailed information about the basic elements used in automotive air conditionersC04 To have detailed information about the installation of air-conditioners used in the automotive industryC05 Used in automotive air conditioners to have detailed information about start upC06 Having information about the automatic control of air-conditionersC07 Having information about the test conditions of air conditioners and evaluation of the results obtained from the tests
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %40
Quizzes 0 %0
Assignment 0 %0
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 16 5 80
Hours for off-the-c.r.stud 14 5 70
Assignments 0 0 0
Presentation 0 0 0
Mid-terms 1 10 10
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 20 20
180 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 5 3 5 4 3 3 5 5 2 3 2 2 3
C01 5 3 5 4 3 3 5 5 2 3 2 2 3
C02 5 3 5 4 3 3 5 5 2 3 2 2 3
C03 5 3 5 4 3 3 5 5 2 3 2 2 3
C04 5 3 5 4 3 3 5 5 2 3 2 2 3
C05 5 3 5 4 3 3 5 5 2 3 2 2 3
C06 5 3 5 4 3 3 5 5 2 3 2 2 3
C07 5 3 5 4 3 3 5 5 2 3 2 2 3
Osmaniye Korkut Ata University
MMB 532 Powder Metallurgy
Credit ECTS
3 3 6Powder Metallurgy
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
R. M. German, Powder Metallurgy & Particulate Materials Processing, MPI 2005, ISBN-10: 0976205718, ISBN-13: 978-0976205715
Ders Notu; Şablon dosyaÖdevler (her hafta)Vize Cevap Anahtarı; Cevap Anahtarı
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
156025
Semester Course Code Course Name L+P
2 MMB 532
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:Teaching powder production techniques. Giving knowledge about shaping of powders by various methods. Introducing sintering theory and applications. Teaching the methods todetermine properties of PM materials.Teaching Methods and Techniques:Metallic powder production techniques: Atomization, chemical, electrolytic and grinding techniques. Characterization of metallic powders. Compacting metallic powders: briquetting,pressing, rolling, extrusion, hot and cold isostatic pressing, powder injection molding. Sintering: Steps, furnaces and gases. Full densification. Mechanical properties of PM materials.Powder systems and applications.Prerequisites:
Course Coordinator:
Instructors:Prof.Dr. Mustafa ÜBEYLİAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Powder production methods2 Powder production methods3 Powder production methods4 Characterization of powders5 Characterization of powders6 Compacting powders7 Compacting powders8 Sintering9 Sintering10 Sintering11 Full density processes12 Mechanical Properties of PM materials13 Mechanical Properties of PM materials14 Mechanical Properties of PM materials
Course Learning Outcomes
No Learning OutcomesC01 Learning powder production methodsC02 Getting information about powder shaping methodsC03 Knowing sintering theory and practiceC04 Ability to determine properties of PM materials.
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %30
Quizzes 0 %0
Assignment 1 %30
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 0 %0
%60 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 16 3 48
Hours for off-the-c.r.stud 16 4 64
Assignments 1 20 20
Presentation 0 0 0
Mid-terms 1 20 20
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 20 20
172 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 5 4 3 3 4 4 4 5 5 5 5 3 4
C01 5 4 3 3 4 4 4 5 5 5 5 3 4
C02 5 4 3 3 4 4 4 5 5 5 5 3 4
C03 5 4 3 3 4 4 4 5 5 5 5 3 4
C04 5 4 3 3 4 4 4 5 5 5 5 3 4
Osmaniye Korkut Ata University
MMB533 Composite Materials
Credit ECTS
3 3 6Composite Materials
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
F.L. Matthews, R.D. Rawlings, Composite Materials: Engineering and Science, CRC Press, 1999, ISBN: 084930251X.M.M. Schwartz, Composite Materials, Prentice-Hall Inc. 1997, ISBN:0-13-300047-8.,L.J. Broutman, R.H. Krock, Modern Composite Materials, Addison-Wesley Publishing Company, Massachusetts, 1967, ISBN: 062117110523.,G. Lubin, Handbook of Composites, VNR Company, NewYork, 1982,Ders Notu; Şablon dosyaÖdev (her hafta)Vize Cevap Anahtarı; Cevap Anahtarı
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
156025
Semester Course Code Course Name L+P
1 MMB533
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:To give information about the composite materials principles, fiber reinforced composites, particle reinforced composites and laminated composites. Having knowledge about fiberreinforcements, fiber types, particle reinforcements and interfaces. To learn application areas of composite materials.Teaching Methods and Techniques:Principles of composite materials. Fiber reinforced composites. Particulate reinforced composites. Laminated composites. Fiber reinforcements. Fiber types. Particulate reinforcements.Properties of interface. Polymers. Thermoplastics. Thermosets and elastomers. Manufacturing methods of composites: Polymer matrix composites, metal matrix composites, ceramicmatrix composites. Mechanical properties of composites. Application fields of composites.Prerequisites:
Course Coordinator:
Instructors:Prof.Dr. Mustafa ÜBEYLİAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 INTRODUCTION TO COMPOSITE MATERIALS2 MATRIX MATERIALS3 FIBERS AND FIBER TYPES4 PARTICULATE REINFORCEMENTS AND INTERFACE PROPERTIES5 POLYMER MATRIX COMPOSITES6 POLYMER MATRIX COMPOSITES7 POLYMER MATRIX COMPOSITES8 METAL MATRIX COMPOSITES9 METAL MATRIX COMPOSITES10 CERAMIC MATRIX COMPOSITES11 CERAMIC MATRIX COMPOSITES12 MECHANICAL PROPERTIES OF COMPOSITES13 TOUGHENING MECHANISMS14 APPLICATION FIELDS OF COMPOSITES
Course Learning Outcomes
No Learning OutcomesC01 Ability to know composite materials typesC02 Learning matrix, reinforcement and interface types.C03 Ability to make and interpret the testing of composite materials.C04 Abiltiy to select composite materials according to application fields.
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %30
Quizzes 0 %0
Assignment 1 %30
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 0 %0
%60 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 16 3 48
Hours for off-the-c.r.stud 16 4 64
Assignments 1 20 20
Presentation 0 0 0
Mid-terms 1 20 20
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 20 20
172 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 5 4 3 3 4 4 4 5 5 5 5 3 4
C01 5 4 3 3 4 4 4 5 5 5 5 3 4
C02 5 4 3 3 4 4 4 5 5 5 5 3 4
C03 5 4 3 3 4 4 4 5 5 5 5 3 4
C04 5 4 3 3 4 4 4 5 5 5 5 3 4
Osmaniye Korkut Ata University
MMB550 Packet Program Applications in Mechanical Engineering
Credit ECTS
3 3 6Packet Program Applications in Mechanical Engineering
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
The usage of Mathematica software
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
304030
Semester Course Code Course Name L+P
1 MMB550
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:To deal with computer aided engineering mechanics problems with MATHEMATICATeaching Methods and Techniques:Face-to-FacePrerequisites:
Course Coordinator:
Instructors:Asist Prof.Dr. Kerimcan ÇELEBİAssistants:Research Assist. Mehmet EKER
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Introduction to the Mathematica software2 Numeracal calculations with Mathematica3 Algebraic calculations with Mathematica4 Symbolic Mathematics with Mathematica5 Numarical Mathematics with Mathematica6 Defining Functions with Mathematica7 Defining Lists with Mathematica8 Plotting with Mathematica9 Mid-term exam10 Structural mechanic problems with mathematica11 Structural mechanic problems with mathematica12 Structural mechanic problems with mathematica13 Structural mechanic problems with mathematica14 Structural mechanic problems with mathematica
Course Learning Outcomes
No Learning OutcomesC01 To learn Mathematica softwareC02 To solve mechanic problems with Mathematica
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %70
Quizzes 0 %0
Assignment 8 %30
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%160 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 5,50 77
Assignments 8 5 40
Presentation 0 0 0
Mid-terms 1 6 6
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 6 6
171 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 3 3 2 4 4 3 2 1 1 1 3 4 1
C01 3 3 2 4 4 3 2 1 1 1 3 4 1
C02 3 3 2 4 4 3 2 1 1 1 3 4 1
Osmaniye Korkut Ata University
MMB551 Structural Dynamics
Credit ECTS
3 3 6Structural Dynamics
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
2030
Semester Course Code Course Name L+P
1 MMB551
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:Machinery and vibration recognition systems to solve practical problems and be able to watch the machine health based on vibration measurements, vibration measurement andvibration analysis ability.Teaching Methods and Techniques:Single degree of freedom systems. Permanent and temporary behavior. Multi-DOF systems. mass and stiffness matrix. Free and forced vibrations. Wave propagation in structures.Prerequisites:
Course Coordinator:
Instructors:
Assistants:
Education Science Health Field
: : : :
20
30
Course Learning Outcomes
No Learning OutcomesC01 Explain the vibration parametersC02 Explain the types of vibrationC03 can remove the frequency response functionC04 able to perform Fourier TransformC05 Able to perfomr basic test in the labsC06 Able to perform vibration analysisC07 vibration measurement and analysis equipment
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %40
Quizzes 0 %0
Assignment 0 %0
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 3 14 42
Hours for off-the-c.r.stud 8 14 112
Assignments 0 0 0
Presentation 0 0 0
Mid-terms 1 5 5
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 10 10
169 Total Work Load
ECTS Credit of the Course 6
Osmaniye Korkut Ata University
MMB552 Numerical Methods in Engineering
Credit ECTS
3 3 6Numerical Methods in Engineering
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
James F. Epperson, 2001, An Introduction to Numerical Methods and Analyses,, John Wiley and Sons, ISBN:0471316474.
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
256015
Semester Course Code Course Name L+P
1 MMB552
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:1.an introduction to the language, logic, and math of numerical methods as used in engineering and the sciences, 2.an opportunity to learn how numerical analyses can be applied toa wide range of problems of importance in the sciences, industry, and societyTeaching Methods and Techniques:
Prerequisites:
Course Coordinator:
Instructors:Asist Prof. Ertuğrul CİHANAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Introduction, Error in numerical analysis,2 Error analysis of functions, least square concepts in numerical methods3 Solution of linear equations systems, Direct methods, Cramer Method, Gauss Elimination4 Gauss Jordan, LU method,5 Jacobi iterative Method6 Gauss Siedel iterative Method, Error Analysis of linear equations systems7 Non linear equation systems, Root finding8 Bisection and Newton Raphson Iteration Methods9 Regula Falsi, Succesive Substitution Method10 Approximation methods, Interpolation, Linear Regression, Interpolation Polynoms11 Lagrange interpolation, Newton Interpolation,12 Numerical integration and differentiation13 Finite difference methods14 Numerical methods for the solution of all problems in a mathematics-based software package
Course Learning Outcomes
No Learning OutcomesC01 The ability to create a mathematical model in engineeringC02 the fundamental knowledge of numerical methods,C03 the ability to use the knowledge about numerical methods in analyzing a problemC04 the ability to choose the right solution method for a particular event,
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %30
Quizzes 0 %0
Assignment 1 %30
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%120 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 6 84
Assignments 1 6 6
Presentation 0 0 0
Mid-terms 1 20 20
Practice 0 0 0
Laboratory 0 0 0
Project 1 20 20
Final examination 0 0 0
172 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P08 P10 P12 P13
All 4 3 5 3 4 5 5 5 4
C01 5 5 3
C02 4
C04 5
Osmaniye Korkut Ata University
MMB559 Advanced Dynamics
Credit ECTS
3 3 6Advanced Dynamics
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Baruh, H., 1999, Analytical dynamics, McGraw-Hill. , Greenwood, D.T., 1977, Classical Dynamics, Prentice-Hall., Lanczos, C., 1962, The Variational Principles of Mechanics, Toronto Press. 6. Press, W.H., et al., 1989, Numerical Recipies, Cambridge Press.
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
305020
Semester Course Code Course Name L+P
1 MMB559
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:Develop an understanding of the fundamental principles of applied kinematics for particles and rigid bodies in engineering dynamics. Demonstrate an integrated understanding ofengineering dynamics principles through applications involving problem solving and through creation of design solutions to engineering scenarios. Work cooperatively to facilitate acollegial atmosphere conducive to learning for all students in the class.Teaching Methods and Techniques:Hamilton's principle. Generalized variables. Lagrange's equations. Rigid body dynamics. Euler angles. Gyroscopic systems under the influence. Three-dimensional dynamics of rigidbodies. Relative velocity and acceleration relations. Element that has characteristics of time varying and non-linear vibration of some systems.Prerequisites:
Course Coordinator:
Instructors:Asist Prof. M. Seha TatlıerAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Basi concepts and introduction to the vector analysis.2 Rigid body dynamics3 Rigid body dynamics4 Euler dynamics5 Euler dynamics6 Lagrange dynamics7 Lagrange dynamics8 Hamilton principle9 Hamilton Principle10 Gyroscope systems11 Gyroscope systems12 Introduction to the vibration theory.13 Vibration analysis14 Vibration analysis
Course Learning Outcomes
No Learning OutcomesC01 Understand the advanced vector analysisC02 Understanding analytical dynamicsC03 Ability to model systems with Euler equationC04 Ability to model systems with Lagrange equationC05 Ability to develop vibrational model with the help of thought materials
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %100
Quizzes 0 %0
Assignment 0 %0
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%160 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 6 84
Assignments 0 0 0
Presentation 0 0 0
Mid-terms 1 20 20
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 30 30
176 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
C01 5 4 5 5 1 2 5 4 3 3 4 3 1
C02 5 4 5 5 1 2 5 4 3 3 4 3 1
C03 5 4 5 5 1 2 5 4 3 3 4 3 1
C04 5 4 5 5 1 2 5 4 3 3 4 3 1
C05 5 4 5 5 1 2 5 4 3 3 4 3 1
Osmaniye Korkut Ata University
MMB 562 Flow Measurement Techniques
Credit ECTS
3 3 6Flow Measurement Techniques
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
"Flow Measurement" ed. by Gustavo Urquiza Beltran and Laura L. Castro Gomez | 2012 | ISBN: 9535103905 9789535103905 |Akışkanlar Mekaniği Temelleri ve Uygulamaları Yunus Çengel, J.M. Cimbala 2008 ISBN 9789756240182
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
103030
Semester Course Code Course Name L+P
2 MMB 562
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:General principles of the measurment techniques. Uncertainity analyses. The characteristics of pitot and static tubes in compressible flow. Velocity measurement tehcniques. Pressuremeasurement techniques. Volume flow rate measurements. Handling of experimental data. Presentation and analysis of results.Teaching Methods and Techniques:Flow measument techniques, Pressure, flow rate and velocity measumentPrerequisites:
Course Coordinator:
Instructors:Asist Prof.Dr. Coşkun ÖZALPAssistants:
Education Science Health Field
: : : : 30
Course Content
Week Topics Study Materials Materials1 General Principles of Measument2 Uncertainity analyses3 Velocity measument Techniques General overview4 Compressible and incompressible flows5 Bernoulli equation Pitot static tube6 Rotometers, Orrifice meters, venturimeters, nozzle type velocity meters, LDA, PIV7 Pressure measurement techniques8 Pressure measurement techniques9 Flow rate measurment techniques10 Flow rate measurment techniques11 Recording experimental data12 Discuusing experimental data13 Presentations14 Presentations
Course Learning Outcomes
No Learning OutcomesC01 Uncertainity analyses is achievedC02 Pressure, velocity and flow rate measurment are knownC03 Different measumanr techniques are known
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %20
Quizzes 0 %0
Assignment 1 %20
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 16 3 48
Hours for off-the-c.r.stud 16 4 64
Assignments 2 10 20
Presentation 2 5 10
Mid-terms 1 10 10
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 20 20
172 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 5 3 4 4 3 2 2 3 4 3 3 5 3
C01 5 3 4 4 3 2 2 3 4 3 3 5 3
C02 4 2 4 4 2 2 3 3 4 3 3 4 3
C03 5 3 3 3 3 2 2 3 4 4 3 4 3
Osmaniye Korkut Ata University
MMB563 Exergy and Entropy Analysis
Credit ECTS
3 3 6Exergy and Entropy Analysis
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Cengel, Y.A., and Boles, M., 2008. Thermodynamics an engineeringapproach. 5th ed., McGraw-Hill.Ibrahim Dincer and Marc A. Rosen, 2007, EXERGY: Energy, Environment and Sustainable Development, Elsevier.
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
203030
Semester Course Code Course Name L+P
1 MMB563
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:• Apply the second law of thermodynamics to processes • Define a new property called entropy to quantify the second-law effects • Establish the increase of entropy principle •Derive the reversible steady-flow work relations • Introduce and apply the entropy balance to various systems. • Examine the performance of engineering devices in light of thesecond law of thermodynamics • Define exergy, which is the maximum useful work that could be obtained from the system at a given state in a specified environment • Define theexergy destruction, which is the wasted work potential during a process as a result of irreversibilities • Define the second-law efficiency • Develop the exergy balance relation • Applyexergy balance to closed systems and control volumesTeaching Methods and Techniques:
Prerequisites:
Course Coordinator:
Instructors:Asist Prof. Ertaç HÜRDOĞANAssistants:
Education Science Health Field
: : : : 20
Course Content
Week Topics Study Materials Materials1 Reviews of Thermodynamics IOverviews and importance of Thermodynamics in real applications; Open-close systems; Control volume; adiabatic process; Isothermal process; Steam table; Conservation of mass; Conservation of energy2 Reviews of Thermodynamics IOverviews and importance of Thermodynamics in real applications; Open-close systems; Control volume; adiabatic process; Isothermal process; Steam table; Conservation of mass; Conservation of energy3 Entropy and increase of entropy principle4 Isentropic processes5 Entropy balance6 Introduction to exergy7 Second law efficiency8 Exergy change of a system9 The decrease of exergy principle and exergy destruction10 Exergy balance-Closed systems11 Exergy balance-Closed systems12 Application of Exergy and entropy analysis to different systems13 Application of Exergy and entropy analysis to different systems14 Application of Exergy and entropy analysis to different systems
Course Learning Outcomes
No Learning OutcomesC01 1) Ability to know Exergy analysis methodsC02 Learning Energy Systems, Life cycle exergy analysisC03 Ability to make exergy calculationsC04 Analyze real energy and material conversion systems from an exergy point of view
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %40
Quizzes 0 %0
Assignment 0 %0
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 3 42
Assignments 1 10 10
Presentation 1 10 10
Mid-terms 1 10 10
Practice 0 0 0
Laboratory 0 0 0
Project 2 15 30
Final examination 1 30 30
174 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 4 4 4 3 5 4 4 5 3 3 4 5 3
C01 3 4 4 3 5 4 4 5 3 3 3 4 3
C02 4 4 4 3 4 4 4 4 4 3 5 5 3
C03 4 3 3 3 5 4 4 4 3 4 4 5 3
C04 4 5 4 4 5 5 4 4 3 3 4 5 3
Osmaniye Korkut Ata University
MMB564 Energy Economics and Management
Credit ECTS
3 3 6Energy Economics and Management
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
EYİCE,S.,"Heat Economy"(in Turkish),Çağlayan Kitabevi,2. Edition,1981Sanayide Enerji Yönetimi Esasları, Elektrik İşleri Etüd İdaresi Generl Müdürlüğü
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
156025
Semester Course Code Course Name L+P
1 MMB564
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:Regulations of energy and management , duties of energy manager, economical analysis methods, gaining back the energy, energy savings in the production and usage of energy atfactories, examples for the energy savings at industries.Teaching Methods and Techniques:
Prerequisites:
Course Coordinator:
Instructors:Asist Prof. Coşkun ÖZALPAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Meeting with students and recognizing the related literature2 Energy Management Systems3 Regulations of Energy Management Systems4 Economical Analysis Methods5 Economical Analysis Methods6 Economical Analysis Methods7 Planning of energy savings8 Planning of energy savings9 Midterm exam10 Gaining back the energy11 Gaining back the energy12 Examples for the energy savings at industries13 Examples for the energy savings at industries14 Examples for the energy savings at industries
Course Learning Outcomes
No Learning OutcomesC01 To be able to obtain information about the examples for the energy savings at industries.C02 Learning energy management systemsC03 Learning economical analysis methodsC04 To recognazie energy gaining backC05 To be able to obtain information about planning of energy savings
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 0 %0
Quizzes 0 %0
Assignment 1 %40
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 16 3 48
Hours for off-the-c.r.stud 16 4 64
Assignments 0 0 0
Presentation 2 10 20
Mid-terms 1 20 20
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 20 20
172 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 3 3 4 3 3 3 3 4 4 2 2 4 3
C01 3 4 4 3 2 3 2 4 4 2 3 4 3
C02 4 3 4 3 2 4 3 3 3 2 2 3 2
C03 3 2 5 3 3 4 2 4 4 2 2 4 4
C04 4 4 4 4 2 3 4 3 2 4 2 4 5
C05 3 4 4 4 4 3 3 4 5 2 2 4 3
Osmaniye Korkut Ata University
MMB567 Cogeneration Systems
Credit ECTS
3 3 6Cogeneration Systems
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Turner, C. Wayne, 2005; Energy Management Handbook
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
155035
Semester Course Code Course Name L+P
1 MMB567
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:Taking advantage of the heat energy in power generation, combined heat and power generation systems and advanced to inform students about design, but also new technologiesand applications to gain knowledge and experienceTeaching Methods and Techniques:Combined heat and power generation (cogeneration). Power plant system structure. Combined heat and power cycle and cycle design. Steam, gas and steam-gas cycle combinedcycle power plants. In the process of energy and exergy analysis, determination of irreversibility. Microcogeneration. Cogeneration technologies. Waste heat recovery. In industrialapplications, the micro cogeneration applications in the automotive industry. Cogeneration importance of energy economics and environmental aspects.Prerequisites:
Course Coordinator:
Instructors:Asist Prof.Dr. Ertaç HÜRDOĞANAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Bileşik ısı güç üretimi (Kojenerasyon).2 Bileşik ısı güç üretimi (Kojenerasyon).3 Güç santrallerinin sistem yapısı.4 Solar energy: principles of solar energy, systems of thermal solar energy5 Solar energy: principles of solar energy, and other applications6 Solar energy: production of electricity with using solar energy and its principles7 Wind Energy: principles of wind energy, and its usage areas8 Presentation of the Homework9 Wind energy potential ,velocity distribution, and introduction to hydraulic energy10 Hydraulic energy: principles of hydraulic energy, turbines, and its usage areas11 Biomass energy: principles of biomass energy, and its usage areas12 Geothermal energy: principles of geothermal energy, and its usage areas13 Wave energy: principles of wave energy, and its usage areas14 Presentations of the projects for evaluation
Course Learning Outcomes
No Learning OutcomesC01 systems and system components to have knowledge about the designC02 To solve the economic analysis of power systemsC03 solutions to complex problems that can be producedC04 show sensitivity to energy and environmental issuesC05 knowledge about new technologies and applications being
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %30
Quizzes 0 %0
Assignment 1 %30
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 0 %0
%60 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 2 28
Hours for off-the-c.r.stud 14 4 56
Assignments 1 20 20
Presentation 2 10 20
Mid-terms 1 25 25
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 25 25
174 Total Work Load
ECTS Credit of the Course 6
Osmaniye Korkut Ata University
MMB 569 Wind Energy Systems Design
Credit ECTS
3 3 6Wind Energy Systems Design
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Wind energy theory and ApplicationWind energy theory and Application,wind energy handbook
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
204040
Semester Course Code Course Name L+P
2 MMB 569
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:With this lesson, students will gain general knowledge about wind energy and apply.Teaching Methods and Techniques:general knowledge, wing energy, wind turbine, maintanance, install, energy policyPrerequisites:
Course Coordinator:
Instructors:Asist Prof.Dr. Bülent YANIKTEPEAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 general knowledge2 general knowledge and wing energy3 determination of wing energy potential4 measuring technique, wind speed, pressure, density5 measuring of wind properties and application6 wind potential of Turkey7 exam8 properties of wind turbine9 vertical and horizantal wind turbine10 installation of wind turbine11 türbine components and transportation12 wind energy policy and condition in the world13 wind energy policy and condition in the world14 cost of turbines and regains
Course Learning Outcomes
No Learning OutcomesC01 can be able to gain general knowledge about wind energyC02 wind energy calculationC03 have knowledge about wind energy potentialC04 can learn the technique of production of energy from wind to electricityC05 apply wind energy systems
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %50
Quizzes 0 %0
Assignment 14 %50
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%160 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 16 3 48
Hours for off-the-c.r.stud 16 1 16
Assignments 5 2 10
Presentation 0 0 0
Mid-terms 1 10 10
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 10 10
94 Total Work Load
ECTS Credit of the Course 3
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
C02 2 2 2 2 2 2 2 2
C03 3 3 3 3
C04 4
Osmaniye Korkut Ata University
MMB571 Turbine Technologies
Credit ECTS
3 3 6Turbine Technologies
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Hydropower Engineering, C. C. Warnick, Howard A. Mayo, Prentice Hall, 1980.• Hydropower Developments: New Projects, Rehabilitation, and Power Recovery by IMechE (Institution of Mechanical Engineers), 2005, Wiley• Hydropower Engineering Handbook (Hardcover) by John S. Gulliver (Author), Roger E. A. Arndt (Author) , Mcgraw-Hill (Tx) (1990)
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
204010
Semester Course Code Course Name L+P
1 MMB571
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:To introduce basic properties and importance of hydraulic turbines in production of energy. To introduce types and constants of hydraulic turbines. To teach and apply basic methodsemployed for selection of turbines and determination of plant capacities.Teaching Methods and Techniques:The course is a technical elective course for energy engineering degree. The course covers the hydropower theory, reaction turbines, hydroelectric systems, hydropower regulationsand efficiency, hydroelectric energy productions.Prerequisites:
Course Coordinator:
Instructors:
Assistants:
Education Science Health Field
: : : :
10
20
Course Content
Week Topics Study Materials Materials1 Introductiom2 Types of Turbines3 Hydro power4 Turbine constants5 Hydro power and hydroulic analyses6 Turbine selection and determination of plant capacity7 Cavitation8 Economical analyses of water power9 Microhydroulic systems10 Midterm exam11 Presentations12 Presentations13 Presentations14 Presentations
Course Learning Outcomes
No Learning OutcomesC01 hydropower theoryC02 Energy conversionsC03 Turbine types and determination of plant capacity
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %25
Quizzes 0 %0
Assignment 5 %10
Attendance 0 %0
Practice 0 %0
Project 1 %15
Final examination 1 %50
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 16 3 48
Hours for off-the-c.r.stud 14 3 42
Assignments 5 4 20
Presentation 0 0 0
Mid-terms 1 15 15
Practice 0 0 0
Laboratory 0 0 0
Project 1 20 20
Final examination 1 20 20
165 Total Work Load
ECTS Credit of the Course 6
P01 P02 P05 P09 P12
All 3 2 4 4 5
C01 3 2 4 4 5
C02 3 2 4 3 4
C03 3 2 4 4 5
Osmaniye Korkut Ata University
MMB 572 Renewable Energy Sources
Credit ECTS
3 3 6Renewable Energy Sources
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Roland Wengenmayr, Renewable Energy : Sustainable Energy Concepts for the Future, John Wiley High Education ,2008,Mustafa Acaroğlu, Alternatif Enerji Kaynakları, Atlas Yayınları, 341 syf, 2003 Hüseyin Öztürk, Yenilenebilir Enerji Kaynakları ve Kullanımı, Teknik yayınevi, 367 syf, 2008. ve Güneş enerjisi ve Uygulamaları, 2012.
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
155035
Semester Course Code Course Name L+P
2 MMB 572
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:• Analysis of renewable energy resources required for modern economies • Scientific principles of renewable energy resources such as solar energy, geothermal energy, hydraulicenergy, and biomass energy are provided for understanding • It is aimed to learn the energy resources for a sustainable development. • It is provided to have knowledge ofrenewable energy resources above national and international policies.Teaching Methods and Techniques:Analysis of renewable energy resources required for modern economies • Scientific principles of renewable energy resources such as solar energy, geothermal energy, hydraulicenergy, and biomass energy are provided for understanding • It is aimed to learn the energy resources for a sustainable development. • It is provided to have knowledge ofrenewable energy resources above national and international policies.Prerequisites:
Course Coordinator:
Instructors:Asist Prof.Dr. Ertaç HÜRDOĞANAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Renewable energy resources and primitive principles2 Potentials and usage areas on the World and Turkey3 Power and energy concepts, Thermodynamics concepts, Energy sources4 Solar energy: principles of solar energy, systems of thermal solar energy5 Solar energy: principles of solar energy, and other applications6 Solar energy: production of electricity with using solar energy and its principles7 Wind Energy: principles of wind energy, and its usage areas8 Presentation of the Homework9 Wind energy potential ,velocity distribution, and introduction to hydraulic energy10 Hydraulic energy: principles of hydraulic energy, turbines, and its usage areas11 Biomass energy: principles of biomass energy, and its usage areas12 Geothermal energy: principles of geothermal energy, and its usage areas13 Wave energy: principles of wave energy, and its usage areas14 Presentations of the projects for evaluation
Course Learning Outcomes
No Learning OutcomesC01 Potential volumes and usage areas of renewable energy resources are learned on Turkey and the World.C02 Identification of energy is known, and renewable energy resources are identified.C03 Production techniques of renewable energy resources are known.C04 Implementation of planned a renewable energy resource is known.C05 Components and their efficiency of renewable energy resources are known.
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %30
Quizzes 0 %0
Assignment 1 %30
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 0 %0
%60 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 2 28
Hours for off-the-c.r.stud 14 4 56
Assignments 1 20 20
Presentation 2 10 20
Mid-terms 1 25 25
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 25 25
174 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 4 4 4 4 5 3 4 4 3 4 3 4 3
C01 3 4 3 4 5 4 4 3 3 4 3 4 3
C02 4 4 4 4 5 3 4 4 3 4 3 4 3
C03 4 4 3 3 3 3 3 5 3 3 3 4 3
C04 3 4 3 4 4 3 4 4 4 4 3 4 3
C05 4 4 4 3 4 3 3 4 3 4 3 4 3
Osmaniye Korkut Ata University
MMB573 Gas Liquid Flows and Heat Transfer
Credit ECTS
3 3 6Gas Liquid Flows and Heat Transfer
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
T.YILMAZ, Gas-Liquid Flows and Heat Transfer,Çukurova Üniversitesi Müh.-Mim. Fak. Yayın No: 38, Adana, 2001.ASHRAE- Handbook,Fundamentals,2009T.YILMAZ, Gas-Liquid Flows and Heat Transfer,Çukurova Üniversitesi Müh.-Mim. Fak. Yayın No: 38, Adana, 2001.Döküman içindeDöküman içinde
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
107020
Semester Course Code Course Name L+P
1 MMB573
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:To give information about the gas-liquid flows and heat transfer.Having knowledge about the flow pattern and calculations of pressure for different flow configerations. To learnprinciples of heat transfer and fluid flow in different gas-liquid flows in practical applications.Teaching Methods and Techniques:INTRODUCTION TO GAS-LIQUID FLOWS FLOW PATTERN BASIC MODELS ANNULAR FLOW EMPRICAL METHODS CONDENSATION BOILING CHOCKED FLOW FLOWAND MASS TRANSFER IN PACKED TOWERS AIR-LIFT PUMPS SUBCOOLED BOILINGPrerequisites:
Course Coordinator:
Instructors:Prof.Dr. Tuncay YILMAZAssistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 INTRODUCTION TO GAS-LIQUID FLOW2 FLOW PATTERN3 BASIC MODELS4 ANNULAR FLOW MODEL5 EMPRICAL RESULTS FOR ANNULAR FLOW6 EMPRICAL METHODS FOR PRESSURE DROP7 CONDENSATION8 BOILING9 CHOCKED FLOW10 FLOW IN PACKED TOWERS11 MASS TRANSFER IN PACKED TOWERS12 AIR-LIFT PUMPS13 EMPRICAL METHODS FOR HEAT TRANSFER14 SUBCOOLED BOILING
Recommended Optional Programme Components
MMB 508 Advanced Convection Heat Transfer
Course Learning Outcomes
No Learning OutcomesC01 Learning pressure drop calculation in gas-liquid flows.C02 Ability to know flow pattern in gas-liquid flows.C03 Ability to understand heat transfer in gas-liquid flows.C04 Learning the different industrial applications of gas-liquid flows.
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %20
Quizzes 0 %0
Assignment 3 %20
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 0 %0
%40 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 4 56
Assignments 3 12 36
Presentation 0 0 0
Mid-terms 1 20 20
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 20 20
174 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
C01 5 2 2 2 5 1 3 4 1 1 1 2 1
C02 5 2 2 2 5 1 3 4 1 1 1 2 1
C03 5 2 2 2 5 1 3 4 1 1 1 2 1
C04 5 2 2 2 5 1 3 4 1 1 1 2 1
Osmaniye Korkut Ata University
MMB 574 Computer Aided Analysis
Credit ECTS
3 3 6Computer Aided Analysis
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Lecture notes,Saeed Moaveni Finite element analysis : theory and application with ANSYSSaeed Moaveni Finite element analysis : theory and application with ANSYS
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
204040
Semester Course Code Course Name L+P
2 MMB 574
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:SeçmeliGoals:To carry out the Computer Aided Analyzes which the students face to their future vocational lifeTeaching Methods and Techniques:Lecture,Question-Answer, Discussion,Drilland Practice, Problem Solving, Project Based LearningPrerequisites:
Course Coordinator:
Instructors:Asist Prof.Dr. Kerimcan ÇELEBİAssistants:Research Assist. Mehmet EKER
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 Introduction to modeling2 Numeric solution technics3 Finite Element Method (FEM)4 Analyzes processing(one, two and three dimensional modeling)5 Analyzes processing(element types and material properties6 Analyzes processing(creating modeling)7 Analyzes processing(mesh modeling)8 Analyzes processing(post processing evaluation)9 The structural analyzes application I with FEM10 Midterm Exam11 The structural analyzes application II with FEM12 The structural analyzes application III with FEM13 The metal forming application I with FEM14 The metal forming application II with FEM
Course Learning Outcomes
No Learning OutcomesC01 The physical situations in the technological field can be modeledC02 The structural static analyzes can be doneC03 The structural dynamic analyzes can be doneC04 The metal forming analyzes can be done
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 1 %60
Quizzes 0 %0
Assignment 8 %40
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%160 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 3,50 49
Assignments 8 5 40
Presentation 0 0 0
Mid-terms 1 6 6
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 6 6
143 Total Work Load
ECTS Credit of the Course 5
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 5 3 3 5 3 4 3 2 2 1 3 5 1
C01 5 3 3 5 3 4 3 2 2 1 3 5 1
C02 5 3 3 5 3 4 3 2 2 1 3 5 1
C03 5 3 3 5 3 4 3 2 2 1 3 5 1
C04 5 3 3 5 3 4 3 2 1 5 1
Osmaniye Korkut Ata University
MMB591 Specialization Field Course
Credit ECTS
4 0 5Specialization Field Course
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Related Literature and Online Resources
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
3030
Semester Course Code Course Name L+P
1 MMB591
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:ZorunluGoals:To make it possible for the students having started their thesis studies have a command of the areas related to their thesis subjects, conduct his/her thesis study and conclude it.Teaching Methods and Techniques:
Prerequisites:
Course Coordinator:
Instructors:Prof.Dr. Tuncay YILMAZAsist Prof.Dr. Önder KAŞKAAsist Prof.Dr. Şaban ÜNALAsist Prof.Dr. Ertuğrul CİHANProf.Dr. Mustafa UBEYLİAsist Prof.Dr. Kerimcan ÇELEBİAsistProf.Dr. Seha TATLIERAsist Prof.Dr. Coşkun ÖZALPAsist Prof.Dr. Bülent YANIKTEPEAsist Prof.Dr. Ertaç HÜRDOĞANAssistants:
Education Science Health Field
: : : : 40
Course Content
Week Topics Study Materials Materials1 What is thesis project?2 What is thesis project?3 How to conduct thesisi project?4 How to conduct thesisi project?5 How to search literature?6 How to search literature?7 How to assess the literature?8 How to assess the literature?9 Basic information on the thesis subject10 Basic information on the thesis subject11 Specific information on the thesis subject12 Specific information on the thesis subject13 Information on the methods to be used in the thesis14 Information on the methods to be used in the thesis
Course Learning Outcomes
No Learning OutcomesC01 To be able to have detailed information on thesis.C02 To be able to have technical know-how on his/her thesis subject.C03 To be able to offer solutions to the problems encountered during the thesis study.
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 0 %0
Quizzes 0 %0
Assignment 0 %0
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %100
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 4 56
Hours for off-the-c.r.stud 14 5 70
Assignments 4 6 24
Presentation 0 0 0
Mid-terms 0 0 0
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 14 14
164 Total Work Load
ECTS Credit of the Course 5
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
C01 3 4 3 3 5 2 4 5 4 4 5 3 3
C02 3 4 3 3 5 2 4 5 4 4 5 3 3
C03 3 4 3 3 5 2 4 5 4 4 5 3 3
Osmaniye Korkut Ata University
MMB592 Specialization Field Course
Credit ECTS
4 0 5Specialization Field Course
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Related Literature and Online Resources
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
3030
Semester Course Code Course Name L+P
2 MMB592
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:ZorunluGoals:To make it possible for the students having started their thesis studies have a command of the areas related to their thesis subjects, conduct his/her thesis study and conclude it.Teaching Methods and Techniques:
Prerequisites:
Course Coordinator:
Instructors:Prof.Dr. Tuncay YILMAZAsist Prof.Dr. Önder KAŞKAAsist Prof.Dr. Şaban ÜNALAsist Prof.Dr. Ertuğrul CİHANProf.Dr. Mustafa UBEYLİAsist Prof.Dr. Kerimcan ÇELEBİAsistProf.Dr. Seha TATLIERAsist Prof.Dr. Coşkun ÖZALPAsist Prof.Dr. Bülent YANIKTEPEAsist Prof.Dr. Ertaç HÜRDOĞANAssistants:
Education Science Health Field
: : : : 40
Course Content
Week Topics Study Materials Materials1 What is thesis project?2 What is thesis project?3 How to conduct thesisi project?4 How to conduct thesisi project?5 How to search literature?6 How to search literature?7 How to assess the literature?8 How to assess the literature?9 Basic information on the thesis subject10 Basic information on the thesis subject11 Specific information on the thesis subject12 Specific information on the thesis subject13 Information on the methods to be used in the thesis14 Information on the methods to be used in the thesis
Course Learning Outcomes
No Learning OutcomesC01 To be able to have detailed information on thesis.C02 To be able to have technical know-how on his/her thesis subject.C03 To be able to offer solutions to the problems encountered during the thesis study.
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 0 %0
Quizzes 0 %0
Assignment 0 %0
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %100
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 4 56
Hours for off-the-c.r.stud 14 5 70
Assignments 4 6 24
Presentation 0 0 0
Mid-terms 0 0 0
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 14 14
164 Total Work Load
ECTS Credit of the Course 5
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
C01 3 4 3 3 5 2 4 5 4 4 5 3 3
C02 3 4 3 3 5 2 4 5 4 4 5 3 3
C03 3 4 3 3 5 2 4 5 4 4 5 3 3
Osmaniye Korkut Ata University
MMB598 Graduate Seminar
Credit ECTS
0 0 7Graduate Seminar
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Literatures of Mechanical Engineering
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
3020
Semester Course Code Course Name L+P
2 MMB598
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:ZorunluGoals:This course is intended to overcome a research and to present the results and to improve the ability to speak in public.Teaching Methods and Techniques:
Prerequisites:
Course Coordinator:
Instructors:
Assistants:
Education Science Health Field
: : : : 50
Course Content
Week Topics Study Materials Materials1 Aim of the c ourse2 seminer assignment3 Literature Survey4 Literature Survey5 Issues tobe considered to preapare a Seminar presantation6 Issues tobe considered to preapare a Seminar presantation7 Preaparing a theoretical subject for seminar8 Preparing results of a research as seminar presantation9 Writing introduction and general informations about a research results10 Writing of material and method section of a paper11 Writing results section of a research article12 Writing results and discussions section of a research article13 Preparing a sample seminar14 Seminar Presantation
Course Learning Outcomes
No Learning OutcomesC01 Belirlediği bir konuda araştırma yapabilir ve seminer verebilir
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 0 %0
Quizzes 0 %0
Assignment 14 %40
Attendance 0 %0
Practice 0 %0
Project 0 %0
Final examination 1 %60
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 2 28
Assignments 14 6 84
Presentation 0 0 0
Mid-terms 0 0 0
Practice 0 0 0
Laboratory 0 0 0
Project 0 0 0
Final examination 1 25 25
179 Total Work Load
ECTS Credit of the Course 6
P01 P02 P03 P04 P05 P06 P07 P08 P09 P10 P11 P12 P13
All 3 4 2 2 3 1 3 5 5 3 4 3 3
C01 3 4 2 2 3 1 3 5 5 3 4 3 3
Osmaniye Korkut Ata University
MMB599 MSc Thesis
Credit ECTS
0 0 25MSc Thesis
Recommended Sources
Textbook Resources Documents Assignments Exams
: : : : :
Tez/seminer/proje konusu ile ilgili literatür
Course Category
Mathmatics and Basic Sciences Engineering Engineering Design Social Sciences
: : : :
303040
Semester Course Code Course Name L+P
3 MMB599
Institute of Natural and Applied SciencesIn the Department of Mechanical Engineering
Language of Instruction:TürkçeCourse Level:
Work Placement(s):NoDepartment / Program:In the Department of Mechanical EngineeringCourse Type:ZorunluGoals:to follow current issues in the thesis and the realization of knowledge transfer.Teaching Methods and Techniques:Students under the supervision of a faculty member on a specific area of theoretical and / practical (experimental) studies as presented by covers.Prerequisites:
Course Coordinator:
Instructors:
Assistants:
Education Science Health Field
: : : :
Course Content
Week Topics Study Materials Materials1 The uses and restrictions of the thesis subject.2 The uses and restrictions of the thesis subject.3 The use and the fucntion of each tool to be used in scientific studies4 The use and the fucntion of each tool to be used in scientific studies5 The use of the tool, software, and equipment related to the research fields6 Theuse of the tool, software, and equipment related to the research fields7 Design of research8 Design of research9 The study will be able to get pre-trial and subsequent detection of disruptions10 Expression of result and methods of the study in tables, graphs,11 Expression of result and methods of the study in tables, graphs,12 The software that will be used in the study13 Analyses and interpretation of the results of the program14 Analyses and interpretation of the results of the program
Course Learning Outcomes
No Learning OutcomesC01 To develop application skills of mathematics, science and engineering knowledgeC02 Design and conduct experiments and analyz eand interpret resultsC03 Possess design skills to meet desired needs a system, component and processC04 An ability to work in multi-disciplinary teamsC05 Very effective verbal and written communication skills abilityC06 Have knowledge and ideain contemporary issuesC07 the ability to use modern engineering devices, techniques required for engineering applications
No Learning Outcome
Program Learning Outcomes
P10 To be conscious and defend highly appraised social, professional and ethical values.P09 To have the ability to effectively communicate verbally and in writing.P08 To evaluate, interpret, and apply the extended and in-depth information obtained during the performing research in the field of Mechanical Engineering.P13 To possess the awareness of the social and environmental aspects of Mechanical Engineering applications.P12 To gain the advanced ability to utilize the tools and equipment employed in Mechanical Engineering applications.P11 To adopt as a principle of the necessity of lifelong learning.P07 To take responsibility for the solution of complex problems related to mechanical engineering, and to develop solutions.P03 Complete the limited or missing information by using the data available and scientific methods and apply, to integrate information across different disciplines.P02 To monitor closely the enhancements in Mechanical Engineering fields and benefits greatly when it is necessary.P01 To obtain highly advance theoretical and practical knowledge and skills in the field of Mechanical Engineering.P06 To comprehend and solve the complex engineering problems by taking the leadership of multi-disciplinary teams.P05 To envision, design and implement Mechanical Engineering related analytical, modeling, and experimental based research, to solve, interpret and present encountered the problems throughout this process.P04 To develop advance innovative ways to solve problems related to Mechanical Engineering.
Course Contribution To Program
Contribution: 1: Very Slight 2:Slight 3:Moderate 4:Significant 5:Very Significant
In-Term Studies Quantity Percentage
Assessment
Mid-terms 0 %0
Quizzes 0 %0
Assignment 0 %0
Attendance 0 %0
Practice 1 %30
Project 1 %70
Final examination 0 %0
%100 Total
Activities Quantity Duration Total Work Load
ECTS Allocated Based on Student Workload
Course Duration 0 0 0
Hours for off-the-c.r.stud 14 15 210
Assignments 0 0 0
Presentation 1 10 10
Mid-terms 0 0 0
Practice 14 12 168
Laboratory 0 0 0
Project 14 25 350
Final examination 0 0 0
738 Total Work Load
ECTS Credit of the Course 25