{"id":1435,"date":"2015-10-26T17:01:21","date_gmt":"2015-10-26T15:01:21","guid":{"rendered":"http:\/\/mep.eng.cu.edu.eg\/?page_id=1435"},"modified":"2015-11-04T08:22:00","modified_gmt":"2015-11-04T06:22:00","slug":"courses_msc_phd","status":"publish","type":"page","link":"https:\/\/mep.eng.cu.edu.eg\/en\/courses_msc_phd\/","title":{"rendered":"Contents of Courses: MSc &amp; PhD"},"content":{"rendered":"<p><\/p>\n<p dir=\"ltr\"><strong>MEP 601 Theory of Fine Measurements:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Introduction and definitions- Error types, sources, and analysis- Static and dynamic response characteristics of measurement systems- Transduction of mechanical signals into electric signals- Conditioning, acquisition, transferring, processing, and displaying of electric signals-Electric methods of measurements- Measurements of force, moment, stress, strain, and vibrations- Measurements of pressure, temperature, and flow rate \u2013 Turbulence measurements of mean and fluctuating flows with focusing on advanced modern methods.<\/p>\n<p dir=\"ltr\"><strong>MEP 602 Computational Methods in Energy Sciences:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Introduction to mathematical models- Finite difference Methods &#8211; Type of 2<sup>nd<\/sup> order differential equations- Numerical methods for solving the Parabolic, Elliptic, and Hyperbolic equations- Conservative Forms \u2013 Finite differences using the upstream and mean value and using mixing of the two values- Numerical converging.<\/p>\n<p dir=\"ltr\"><strong>MEP 603 Advanced Fluid Dynamics:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Complete sets of governing equations of fluid flow &#8211; Integral and differential control volume analysis methods \u2013 Mathematical solutions of equati ons of fluid motion- Computational Fluid Dynamics \u2013 Typical examples and practical applicati ons for viscous and frictionless or ideal flows \u2013 Differential analysis of Boundary Layer The ory \u2013 Introduction to compressible flows and Aerodynamics.<\/p>\n<p dir=\"ltr\"><strong>MEP 604 Turbulent Flow:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Introduction to Turbulence- Origin, nature, and characteristics of turbulence- Different analysis methods of turbulence- Mixing, diffusion, and multi-length scales of turbulence-Theories of viscous vorticity and mixing length scale- General equations governing conservation of mass, momentum, energy, and conservation of vorticity- Different typical patterns of turbulent flows: Wakes, Free Jets, Boundary Layers- Spectral dynamics and statistical analysis of turbulence- Experimental methods for turbulent measurements.<\/p>\n<p dir=\"ltr\"><strong>MEP 605 Two-Phase Flow:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Introduction- Two and multiphase flows- Theory of Homogenous two phase flow- Theory of Separated two phase flows- Distribution of velocity and concentration- The 1-D wave theory \u2013 The interference phenomenon and behavior of thin layers.<\/p>\n<p dir=\"ltr\"><strong>MEP 606 Turbo-Machinery:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Driving the basic equations for fluid machinery and its applications \u2013 Theory of Similarity in fluid machinery- 1-D flow in turbo-machines- Theoretical calculation of flow in set of blades Experimental data of flow in blades\u2013 3-D flow throu gh blade-cascades of turbo-machines-Solution methods for 3-D flow in turbo-machines.<\/p>\n<p dir=\"ltr\"><strong>MEP 607 Gas Dynamics:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Basic concepts of compressible flow- Isentropic ideal flow- Flow in converging nozzles \u2013 Normal shock waves- Oblique shock waves- Fanno-line flow- Isothermal flow \u2013 Rayliegh line flow \u2013 Prandtl flow \u2013 Theory of expansion of waves \u2013 Method of characteristics-Computational and numerical methods for solving compressible flow equations.<\/p>\n<p dir=\"ltr\"><strong>MEP 608 Computational Methods in Fluid Dynamics:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Governing equations of fluid motion- Principles of numerical analysis- Stability of numerical methods- Convergence of the numerical method to a solution- Solution of incompressible and compressible flows- The Turbulent flow models \u2013 Acoustics aerodynamics- Correction of the boundaries of solution field- Generation of mesh of solution- Diagrammatic presentation drawings.<\/p>\n<p dir=\"ltr\"><strong>MEP 609 Transient Unsteady Fluid dynamics:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Transient unsteady flows in pipes and rotating machines- Sound wave generated by air motion- Unsteady turbulent flow- Turbulence in combustion- Computational methods for unsteady flows.<\/p>\n<p dir=\"ltr\"><strong>MEP 610 Environmental Fluid Dynamics:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Basic definitions \u2013 Specifications and laws for env ironmental protection- Main sources for environmental pollution- Governing equations for atmospheric air flow- cooling of gases in air \u2013 Control of pollution from fixed and moving so urces \u2013 Treatment of industrial liquids \u2013 Domestic Water treatment \u2013 Drains treatment.<\/p>\n<p dir=\"ltr\"><strong>MEP 611 Viscous Flow:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Governing equations of boundary layer flow- Laminar boundary layer on a flat plate without and with variable pressure gradient \u2013 Thermal Bound ary layer in laminar flow- Boundary layer in compressible flow- Turbulent boundary layer on a flat plate with zero pressure gradient- Introduction to computational methods for boundary layer flows.<\/p>\n<p dir=\"ltr\"><strong>MEP 612 Advanced Thermodynamics:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">General Relations of Thermodynamics- Equations of State- Real Gases- Third Law of Thermodynamics- Properties of Solutions and Mixtures \u2013 Thermodynamic Stability and equilibrium \u2013 Thermodynamics of reacting systems- Basics and Principles of Statistical Thermodynamics.<\/p>\n<p dir=\"ltr\"><strong>MEP 613 Fundamentals of Combustion:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Combustion Reactions- Fuels: types, specifications, and properties- Flames: types, theories, and stability- Heat release and transfer from flames- Fuel Atomization: mechanisms and tools-Combustion chambers for solid, liquid and gaseous fuels- Measurements in flames and combustion systems.<\/p>\n<p dir=\"ltr\"><strong>MEP 614 Advanced Measurement Methods:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Hot-Wire Measurements: theory and basics- Measurements of fluctuating velocities and temperature- Effect of resistance ratio- Calibration- Experimental tests- Measurements using Laser Anemometer: theory and basics \u2013 Theory of Wav es and velocity measurements using Laser Anemometer- The effect of light scattering \u2013 Particles volume and concentration-Statistical properties- Signals conditioning and data acquisition and processing- Applications.<\/p>\n<p dir=\"ltr\"><strong>MEP 615 Theory of Reciprocating Combustion Engines:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Properties of working medium- Simulation of Cycles- Mathematical models- Mechanisms of air, fuel, and exhaust- Combustion and Pollutants- Heat and mass losses- Friction-Performance of ordinary and supercharging engines.<\/p>\n<p dir=\"ltr\"><strong>MEP 616 Lubrication Theories:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Principals of lubrication- Reynolds equation and its limiting conditions- Algebraic solution of Reynolds equation for special cases- Numerical solution of Reynolds equation in case of axial and forced bearings- Hydrostatic bearings.<\/p>\n<p dir=\"ltr\"><strong>MEP 617 Fundamentals of Air Pollution:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Introduction- Main air pollutants and its effect- Standard specifications of clean air- Main sources of air pollution- Methods of control of pollutants emissions- Methods of pollutants detection, measuring and tracing.<\/p>\n<p dir=\"ltr\"><strong>MEP 618 Fires and Explosions:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Basics and characteristics of fires- Fire protection strategies \u2013 Fire dynamics \u2013 Fire protection tools and devices- Explosions of closed and semi-closed containers- Blast Waves \u2013 Explosions Safety Methods.<\/p>\n<p dir=\"ltr\"><strong>MEP 619 Computational Methods in Combustion:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Review of chemical thermodynamics- Kinetics of combustion- Equations Governing multi-components reaction systems- Simple models for combustion- Mathematical models for reactive flow- Finite differences- Diffusion and Pre-mixed Flame Models- Computational methods for two-phase reactive flow- Practical applications for combustors simulation.<\/p>\n<p dir=\"ltr\"><strong>MEP 620 Atomization and Spray:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Mechanism of atomization- Methods of atomization- Design of spray nozzles- Analysis and calculations of sprays- Evaporation and combustion of a single droplet- Evaporation and combustion of sprays- Combustors of liquid fuels.<\/p>\n<p dir=\"ltr\"><strong>MEP 621 Advanced Heat Transfer:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Thermal Conduction: definitions, conduction general equation- 3-d conduction- Mathematical and algebraic methods- Thermal convection: definitions, thermal boundary layer, governing equations- Flow through passages- Heat Transfer in fires and flames- Thermal Radiation: Governing equations, design of boiler furnaces- Boiling and Condensation- Examples- Mass Transfer: governing equations- Transport phenomena.<\/p>\n<p dir=\"ltr\"><strong>MEP 622 Thermal Convection:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Heat Transfer Coefficient- Dimensionless analysis- Analytical methods for heat transfer calculations- Governing equations for conservation of mass, momentum, and energy- Flow and heat transfer in pipelines and air ducts- Laminar cooling- Flow of free jets.<\/p>\n<p dir=\"ltr\"><strong>MEP 623 Thermal Conduction:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Introduction-General Equation of thermal conduction- 1-D thermal conduction in case of no heat generation and case of heat generation- Fines and extended surfaces- 2-D and 3-D thermal conduction- Numerical methods- Solving unsteady thermal conduction using Laplace equation.<\/p>\n<p dir=\"ltr\"><strong>MEP 624 Thermal Radiation (1):<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Fundamentals- Perfect Black Bodies- Radiation properties and characteristics of surfaces-Radiation of real and transparent bodies- Radiation transfer between simple shapes-Coefficient of relative position- Radiation transfer in black vessels.<\/p>\n<p dir=\"ltr\"><strong>MEP 625 Thermal Radiation (2):<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Thermal radiation in gases-Radiation in absorbing, emissive, and scattering materials-Methods of calculating the relative position coefficient \u2013 Radiation transfer in non-black vessels- Monte Carlo Method.<\/p>\n<p dir=\"ltr\"><strong>MEP 626 Solar Energy, Collection and Storage:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Introduction- Solar angels Engineering-Extraterrestrial and on-ground solar radiation: its nature, characteristics, and quantity- Measurement methods for solar radiation- Transmission of solar radiation through transparent and partially transparent media- Radiation characteristics of different types of surfaces- Shading calculations- Collection of solar energy-Flat plate collectors- Concentrators- Storage.<\/p>\n<p dir=\"ltr\"><strong>MEP 627 Solar Energy Utilization:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Classification of applications according to temperature levels- Heating of Fluids and buildings- Cooling and Air-conditioning- Passive and non-passive systems- Drying of products- Water desalination- Water pumping \u2013 Power generation using solar energy-Economics of solar systems.<\/p>\n<p dir=\"ltr\"><strong>MEP 628 Power Stations:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Power generation and consumption- Types of power stations \u2013 Steam power stations- Gas turbine power stations- Diesel engine power stations- Combined cycle power stations-Cogeneration- Nuclear power stations- Energy storage- Power stations and the environmental pollution.<\/p>\n<p dir=\"ltr\"><strong>MEP 629 Refrigeration:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Main components of vapor-compression refrigeration systems: types, operation and performance- Matching of system components- Absorption refrigeration- Thermo-electric refrigeration- Gas liquidification- Optimum design of refrigeration system- Energy utilization in refrigeration- Types of refrigerants and comparison among them<\/p>\n<p dir=\"ltr\"><strong>MEP 630 Nuclear Engineering:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Introduction- Principles of nuclear physics and reactors physics- Nuclear fission or fusion-Nuclear radiations- Calculations of reactor-core- Protection from nuclear radiations- Neutron cycles and reactor control- Nuclear power stations- Reactor safety \u2013 Selection and Testing of the locations of nuclear power stations.<\/p>\n<p dir=\"ltr\"><strong>MEP 631 Energy Storage and Recovery:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Types and energy forms- The need for energy storage- Storage capacity evaluation- Methods of energy storage- Mechanical energy storage- Water pumping- Compressed air- Storage of thermal energy- Storage of sensible heat- Storage in liquids and solids- storage in phase changing materials- Heat exchangers for energy storage- Energy storage in refrigeration systems-Ice storage \u2013 chilled water storage- Chemic al storage.<\/p>\n<p dir=\"ltr\"><strong>MEP 632 Numerical Methods in Heat Transfer:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Introduction-Governing equations- Thermal conduction in multi-dimensions-Convection and diffusion-Different numerical solution methods-General applications.<\/p>\n<p dir=\"ltr\"><strong>MEP 633 Thermal Design of Electronic Systems:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Introduction- Review of heat transfer basics- Classification of electronic systems- Thermal circuits and networks- Thermal resistance of contacting surfaces- Heat exchangers- Air forced cooling- Design for special cases.<\/p>\n<p dir=\"ltr\"><strong>MEP 634 Advanced Psychrometry and Its Applications:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Psychometric charts and processes- Processes of Air-Water direct contact- Enthalpy difference- Air washers- Cooling Towers \u2013 Water spr ay dehumidification- Cooling coils \u2013 Dehumidification by absorption materials.<\/p>\n<p dir=\"ltr\"><strong>MEP 635 Special Course:<\/strong><\/p>\n<p dir=\"ltr\">Special topics course.<\/p>\n<p dir=\"ltr\"><strong>LAN 601 Technical Languish and Report Writing:<\/strong><\/p>\n<p dir=\"ltr\">Special Mandatory course in Technical English Languish and Report Writing.<\/p>\n<p dir=\"ltr\"><strong>MEP 641 Special Elected Topics (1):<\/strong><\/p>\n<p dir=\"ltr\">Special course.<\/p>\n<p dir=\"ltr\"><strong>MEP 642 Special Elected Topics (2):<\/strong><\/p>\n<p dir=\"ltr\">Special course.<\/p>\n<p dir=\"ltr\"><strong>MEP 699 (mandatory course for Master of Science Degree) M. Sc. Thesis:<\/strong><\/p>\n<p dir=\"ltr\">\n<ol>\n<li>Sc. Thesis work according to the field of specialization. It is equivalent to a total of 18 credit hours.<\/li>\n<\/ol>\n<p dir=\"ltr\"><strong>MEP 741 Advanced Elected Topics (1):<\/strong><\/p>\n<p dir=\"ltr\">Special course.<\/p>\n<p dir=\"ltr\"><strong>MEP 742 Advanced Elected Topics (2):<\/strong><\/p>\n<p dir=\"ltr\">Special course.<\/p>\n<p dir=\"ltr\"><strong>MEP 799 (mandatory course for The Ph. D. Degree) Ph. D. Dissertation:<\/strong><\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">Ph. D. Dissertation work according to the field of specialization. It is equivalent to a total of 30 credit hours.<\/p>\n<p dir=\"ltr\">\n<p dir=\"ltr\">\n<p dir=\"ltr\">\n<p dir=\"ltr\">\n<p><\/p>","protected":false},"excerpt":{"rendered":"<p>MEP 601 Theory of Fine Measurements: Introduction and definitions- Error types, sources, and analysis- Static and dynamic response characteristics of measurement systems- Transduction of mechanical signals into electric signals- Conditioning, acquisition, transferring, processing, and displaying of electric signals-Electric methods of measurements- Measurements of force, moment, stress, strain, and vibrations- Measurements of pressure, temperature, and flow [&hellip;]<\/p>\n","protected":false},"author":21,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"open","ping_status":"open","template":"","meta":{"footnotes":""},"class_list":["post-1435","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/mep.eng.cu.edu.eg\/en\/wp-json\/wp\/v2\/pages\/1435","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/mep.eng.cu.edu.eg\/en\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/mep.eng.cu.edu.eg\/en\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/mep.eng.cu.edu.eg\/en\/wp-json\/wp\/v2\/users\/21"}],"replies":[{"embeddable":true,"href":"https:\/\/mep.eng.cu.edu.eg\/en\/wp-json\/wp\/v2\/comments?post=1435"}],"version-history":[{"count":3,"href":"https:\/\/mep.eng.cu.edu.eg\/en\/wp-json\/wp\/v2\/pages\/1435\/revisions"}],"predecessor-version":[{"id":1566,"href":"https:\/\/mep.eng.cu.edu.eg\/en\/wp-json\/wp\/v2\/pages\/1435\/revisions\/1566"}],"wp:attachment":[{"href":"https:\/\/mep.eng.cu.edu.eg\/en\/wp-json\/wp\/v2\/media?parent=1435"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}