•
•           Information on Degree Programmes

COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
Fluid Mechanics I * IMZ   305 5 3 3 5

 Prerequisites and co-requisites Yok Recommended Optional Programme Components None

Language of Instruction Turkish
Course Level First Cycle Programmes (Bachelor's Degree)
Course Type
Course Coordinator Prof. Dr. Mevlüt Sami AKÖZ
Instructors
 Prof. Dr. MEVLÜT SAMİ AKÖZ 1. Öğretim Grup:A Prof. Dr. MEVLÜT SAMİ AKÖZ 2. Öğretim Grup:A

Assistants
Goals
To teach the the basic equations governing the behavior of fluids at rest and in motion and their applications
Content
Properties of fluids: Compressibility, Viscosity, Surface tension, Vapor pressure, Hydrostatic pressure and forces, Hydrostatic pressure due to linear acceleration and uniform rotation, Basic equations of flow and metods of analysis, Classification of flow, Continuity equation, Convective motion of fluid element, Circulation, Stream function, Velocity potential function, Flow net, Conservation of momentum, Euler equation of motion, Bernoulli equation and its applications, Curvilinear flows, Conservation of moment of momentum, Turbines and pumps.

Learning Outcomes
-

Course's Contribution To Program
NoProgram Learning OutcomesContribution
12345
1
Has the basic knowledge of math, science and civil engineering
2
Has a good commman of basic concepts, theories and principles in civil engineering.
3
Independently reviews and learns the applications, makes a critical assessment of the problems faced with, selects the proper technique to formulate problems and propose solutions
X
4
Designs a system, a component or a process in order to meet the needs of various engineering problems within technical, economic, environmental, manufacturability, sustainability limitations.
X
5
Selects and uses the modern techniques and tools necessary for engineering practice
6
Designs and carries out experiments in the fields of civil engineering, and interprets the results and the data obtained from the experiments
X
7
Gains the abiltiy to work effectively as a member in interdisciplinary teams
8
Identifies proper sources of information and databases, reaches them and uses them efficiently.
X
9
Follows the advancements in science and technology being aware of the necessity of lifelong learning and continuously improves her/himself.
X
10
Uses the computers and information technologies related with civil engineering actively.
X
11
Gains the ability to communicate effectively both orally and in writing.
12
Communicates using technical drawing
13
Constantly improves her/himself by identifying the training needs in scientific, cultural, artistic and social fields.
X
14
Continuously improves her/himself by defining necessities in learning in scientific, social, cultural and artistic areas besides the occupational requirements.
15
Has an understanding of entrepreneurship and innovation subjects, and is knowledgeable of contemporary issues.
X
16
Has an awareness of professional and ethical responsibility
X
17
Has the required knowledge in project management, workplace practices, employee health, environmental and occupational safety; and the legal implications of engineering applications.
X

Course Content
WeekTopicsStudy Materials _ocw_rs_drs_yontem
1 Properties of fluids: Compressibility, Viscosity, Surface tension, Vapor pressure
2 Hydrostatic pressure; definition, variation and measurement Revision of previous lecture
3 Hydrostatic forces on submerged surfaces and bodies Revision of previous lecture
4 Hydrostatic pressure for liquids subject to linear acceleration and uniform rotation Revision of previous lecture
5 Kinematics of fluid flow; Basic equations and methods of analysis, Classification of flows Revision of previous lecture
6 Acceleration of fluid, Continuity equation in control volume and differential control volume approach, Convective motion of fluid element Revision of previous lecture
7 Circulation in fluid flow, Stream function, Velocity potential function, Flow net Revision of previous lecture
8 Mid-Term Exam
9 Conservation of momentum using differential control volume approach, Euler equation of motion, Pressure and velocity in the flow, Bernoulli equation and its applications
10 Bernoulli equation and its applications Revision of previous lecture
11 Curvilinear flows Revision of previous lecture
12 Conservation of momentum for an inertial reference and its applications Revision of previous lecture
13 Consevation of momentum for a control volume moving with constant velocity and its applications, Consevation of mement of momentum Revision of previous lecture
14 Turbines and pumps; Application of momentum equations to Pelton, Francis and Kaplan turbines, and rotodynamic pumps Revision of previous lecture
15 Characteristics of turbines and pumps Revision of previous lecture
16-17 Term Exams