Fluid Mechanics (ΕΜ4): Διαφορά μεταξύ των αναθεωρήσεων

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[[Graduate Courses Outlines]] - [https://math.uoi.gr  Department of Mathematics]
* [[Ρευστομηχανικη (ΕΜ4)|Ελληνική Έκδοση]]
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=== General ===
=== General ===
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|-
|-
! Course Code
! Course Code
| EM4A
| EM4
|-
|-
! Semester
! Semester
Γραμμή 47: Γραμμή 49:
|-
|-
! Learning outcomes
! Learning outcomes
| The course is an introduction to the analytical and numerical methods of Fluid Mechanics. The objectives of the course are:
|
# Development of the theoretical background of the postgraduate student in matters relating to Fluid Mechanics and ability of the student to apply analytical, approximate and numerical methods in Fluid Mechanics problems.
The course is an introduction to the analytical and numerical methods of Fluid Mechanics. The objectives of the course are:
# Upon completion of the course the graduate student will be able to solve problems with analytical, approximate or numerical methods and further deepen the understanding of such methods.
* Development of the theoretical background of the postgraduate student in matters relating to Fluid Mechanics and ability of the student to apply analytical, approximate and numerical methods in Fluid Mechanics problems.
* Upon completion of the course the graduate student will be able to solve problems with analytical, approximate or numerical methods and further deepen the understanding of such methods.
|-
|-
! General Competences
! General Competences
| The course aims to enable the postgraduate student to:
|
# Develop the ability to analyse and synthesize basic knowledge of Fluid Mechanics.
The course aims to enable the postgraduate student to:
# Adapt to new situations.
* Develop the ability to analyse and synthesize basic knowledge of Fluid Mechanics.  
# Decision-making.
* Adapt to new situations
# Working independently
* Decision-making  
# Team work.
* Working independently
 
* Team work
All the above will give to the stundetns the opportunity to work in an international multidisciplinary environment.
All the above will give to the students the opportunity to work in an international multidisciplinary environment.
|}
|}


=== Syllabus ===
=== Syllabus ===


Kinematics of Fluids, Fluid flow analysis, Equation of continuity and stream function, motion equations for Ideal and real fluids, laminar and turbulent flow, Boundary layer flows with adverse pressure gradient, Numerical Methods in Fluid Mechanics, Classification of fluid dynamics problems and relevant equations that describe basic numerical schemes, method of finite differences, compatibility, stability and convergence of numerical schemes, finite volume method, Introduction to the method of weighted residues, finite element method. The course includes training in computational methods in the computer laboratory (Mechanics lab).
Kinematics of Fluids, Fluid flow analysis, Equation of continuity and stream function, motion equations for Ideal and real fluids, laminar and turbulent flow, Boundary layer flows with adverse pressure gradient, Numerical Methods in Fluid Mechanics, Classification of fluid dynamics problems and relevant equations that describe basic numerical schemes, method of finite differences, compatibility, stability and convergence of numerical schemes, finite volume method, Introduction to the method of weighted residues, finite element method. The course includes training in computational methods in the computer laboratory (Applied and Computational Mathematics Laboratory).


=== Teaching and Learning Methods - Evaluation ===
=== Teaching and Learning Methods - Evaluation ===
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|-
|-
! Delivery
! Delivery
| In the class
|
In class
|-
|-
! Use of Information and Communications Technology
! Use of Information and Communications Technology
| Use of computer (Mechanics) lab
|
Use of computer lab (Applied and Computational Mathematics Laboratory).
|-
|-
! Teaching Methods
! Teaching Methods
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| 39
| 39
|-
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| Study and analysis of bibliography
| Study study
| 78
| 78
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|-
| Preparation of assignments and interactive teaching
| Homework - Projects
| 70.5
| 70.5
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|-
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=== Attached Bibliography ===
=== Attached Bibliography ===


# Fluid Mechanics, Volume 1, A. Papaioanou, 2nd Edition, 2001 (in Greek).
<!-- In order to edit the bibliography, visit the webpage -->
# Computational Fluid Mechanics, I. Soulis, 1st Edition, 2008 (in Greek).
<!-- https://wiki.math.uoi.gr/index.php/%CE%A0%CF%81%CF%8C%CF%84%CF%85%CF%80%CE%BF:MAM157-Biblio -->
# Numerical heat transfer and fluid flow, S.V. Patankar, McGraw-Hill, New York, 1980.
 
# The Finite Element Method, Vol. 1, The Basis, O.C. Zienkiewicz, R.L. Taylor, 5th Ed., Butterworth-Heinemann, Oxford, 2000.
{{MAM157-Biblio}}
# Computational Techniques for fluid Dynamics, C.A.J. Fletcher Volumes I and II, 2nd Ed. Springer-Verlag, Berlin, 1991.

Τελευταία αναθεώρηση της 05:15, 16 Ιουνίου 2023

General

School School of Science
Academic Unit Department of Mathematics
Level of Studies Graduate
Course Code EM4
Semester 2
Course Title Fluid Mechanics
Independent Teaching Activities Lectures (Weekly Teaching Hours: 3, Credits: 7.5)
Course Type Special Background
Prerequisite Courses -
Language of Instruction and Examinations Greek
Is the Course Offered to Erasmus Students Yes (in English)
Course Website (URL) See eCourse, the Learning Management System maintained by the University of Ioannina.

Learning Outcomes

Learning outcomes

The course is an introduction to the analytical and numerical methods of Fluid Mechanics. The objectives of the course are:

  • Development of the theoretical background of the postgraduate student in matters relating to Fluid Mechanics and ability of the student to apply analytical, approximate and numerical methods in Fluid Mechanics problems.
  • Upon completion of the course the graduate student will be able to solve problems with analytical, approximate or numerical methods and further deepen the understanding of such methods.
General Competences

The course aims to enable the postgraduate student to:

  • Develop the ability to analyse and synthesize basic knowledge of Fluid Mechanics.
  • Adapt to new situations
  • Decision-making
  • Working independently
  • Team work

All the above will give to the students the opportunity to work in an international multidisciplinary environment.

Syllabus

Kinematics of Fluids, Fluid flow analysis, Equation of continuity and stream function, motion equations for Ideal and real fluids, laminar and turbulent flow, Boundary layer flows with adverse pressure gradient, Numerical Methods in Fluid Mechanics, Classification of fluid dynamics problems and relevant equations that describe basic numerical schemes, method of finite differences, compatibility, stability and convergence of numerical schemes, finite volume method, Introduction to the method of weighted residues, finite element method. The course includes training in computational methods in the computer laboratory (Applied and Computational Mathematics Laboratory).

Teaching and Learning Methods - Evaluation

Delivery

In class

Use of Information and Communications Technology

Use of computer lab (Applied and Computational Mathematics Laboratory).

Teaching Methods
Activity Semester Workload
Lectures 39
Study study 78
Homework - Projects 70.5
Course total 187.5
Student Performance Evaluation
  1. Weekly assignments
  2. Final project
  3. Written examination at the end of the semester

Attached Bibliography

  • Fluid Mechanics with Applications, M. Xenos and E. Tzirtzilakis, 2018 (in Greek)
  • Fluid Mechanics, Volume 1, A. Papaioanou, 2nd Edition, 2001 (in Greek).
  • Computational Fluid Mechanics, I. Soulis, 1st Edition, 2008 (in Greek).
  • Numerical heat transfer and fluid flow, S.V. Patankar, McGraw-Hill, New York, 1980.
  • The Finite Element Method, Vol. 1, The Basis, O.C. Zienkiewicz, R.L. Taylor, 5th Ed., Butterworth-Heinemann, Oxford, 2000.
  • Computational Techniques for fluid Dynamics, C.A.J. Fletcher Volumes I and II, 2nd Ed. Springer-Verlag, Berlin, 1991.