Course Syllabus

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SYLLABUS

Fluid Mechanics

Semester & Location:

Spring 2026 - DIS Stockholm
Type & Credits:

Elective course - 3 credits

Faculty:

Konstantinos Missios
- Contact via Canvas Inbox

Time:

Thursdays at 18:00-20:55

Classroom:

1D-410

Major Disciplines:

Engineering, Physics / Biophysics

Related Disciplines:

Prerequisites:

One course in multivariate calculus, one course in differential equations, a physics or engineering course covering statics and dynamics, all at university level. It is recommended to have taken Thermodynamics or to enroll in Thermodynamics the same term.

Program Contact:

CE@dis.dk
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M.C. Escher, Sky and Water II, woodcut, December 1938

 

Course Description

Fluid mechanics is the  studies the behavior of fluids, liquids and gases, and how those interact with their surroundings under the presence of internal and external forces. Fluid flows are omnipresent in, natural phenomena, industrial applications but also our everyday lives.

This course will cover fundamental concepts of fluid mechanics, including fluid statics, fluid kinematics, fluid dynamics, dimensional analysis and similitude, laminar and turbulent, internal flow, and boundary layers. Students will apply fluid mechanics concepts while working on exercises and solving problems. In addition, students will have the opportunity to participate in field studies and witness current research and developments in Sweden that rely on fluid mechanics.

The course will cover the following modules:

  1. Introduction and Basic Concepts
    1. Introduction
    2. The No-Slip Condition
    3. A Brief History of Fluid Mechanics
    4. Classification of Fluid Flows
  2. Properties of Fluids
    1. Density and Specific Gravity
    2. Vapor Pressure and Cavitation
    3. Viscosity 
    4. Surface Tension and Capillary Effect

  3. Pressure and Fluid Statics

    1. Pressure

    2. The Manometer

    3. The Barometer and Atmospheric Pressure

    4. Hydrostatic forces on Plane and Curved Surfaces

  4. Fluid Kinematics

    1. Lagrangian and Eulerian Descriptions
    2. Fundamentals of Flow Visualization
    3. The Reynolds Transport Theorem

  5. Bernoulli and Energy Equations

    1. Conservation of Mass
    2. Mechanical Energy and Efficiency
    3. The Bernoulli Equation
    4. General Energy Equation

  6. Momentum Analysis of Flow Systems

    1. Newton’s Laws and Conservation

      of Momentum
    2. Control Volume Analysis
    3. The Linear Momentum Equation 
    4. The Angular Momentum Equation 

  7. Dimensional Analysis and Modeling

    1. Dimensions and Units 
    2. Dimensional Homogeneity
    3. Nondimensionalization of Equations
    4. Dimensional Analysis and Similarity
    5. The Buckingham Pi Theorem

  8. Internal Flow

    1. Laminar and Turbulent Flows
    2. Laminar Flow in Pipes
    3. Turbulent Flow in Pipes

  9. Differential Analysis of Fluid Flow

    1. Conservation of Mass—The Continuity
      Equation 
    2. The Stream Function
    3. The Navier–Stokes Equation
    4. Differential Analysis of Fluid Flow
      Problems

  10. Approximate Solutions of the Navier-Stokes Equation

    1. The Creeping Flow Approximation
    2. Approximation for Inviscid Regions
      of Flow
    3. The Irrotational Flow Approximation
    4. The Boundary Layer Approximation

  11. External Flow: Drag and Lift

    1. Drag and Lift

    2. Friction and Pressure Drag 

    3. Drag Coefficients of Common Geometries

    4. Parallel Flow over Flat Plates

    5. Flow over Cylinders and Spheres

    6. Lift

Learning Objectives

By the end of this course, students will be able to:

  • Understand principles of fluid mechanics covered in all modules
  • Analyze fluid flows through the use of fluid mechanics principles and appropriate modeling
  • Identify fluid-flow phenomena in various engineering systems, such as pipes, and apply their knowledge to assess physical implications
  • Reflect on the importance of fluid mechanics in natural systems and engineering applications 

Faculty

Konstantinos Missios, PhD

Readings

Cengel and Cimbala's Fluid Mechanics: Fundamentals and Applications 2024 Release by Yunus A. Cengel and John M. Cimbala

Field Studies

We will have two course-integrated field studies to learn how fluid dynamics concepts are utilized in industry or research. 

Field studies may include:

Visit to laboratories at Kungliga Tekniska Högskola (Royal Institute of Technology), Stockholm, Sweden

Visit to laboratories at Karolinska Institutet, Stockholm, Sweden

Guest Lecturers

Guest lecturers (experts in a particular area of fluid mechanics) may be invited to talk about topics of particular interest to students.

Approach to Teaching

We use various teaching methods, including interactive lectures, class exercises, problem solving, discussions, analysis of various applications during field studies. 

DIS Accommodations Statement 

If you have approved academic accommodations with DIS, please make sure the teacher receives your DIS accommodations letter within two weeks from the start of classes. If you can think of other ways the teacher can support your learning, please do not hesitate to let the teacher know. If you have any further questions about your academic accommodations, contact Academic Support acadsupp@dis.dk. 

Expectations of the Students

  • You should participate actively during lectures, discussions, group work, and exercises.
  • Laptops may be used for note‐taking, fact‐checking, or assignments in the classroom, but only when indicated by the instructor. At all other times, laptops and electronic devices should be put away during class meetings.
  • Readings must be done prior to the class session. 
  • In addition to completing all assignments and exams, you need to be present, arrive on time, and actively participate in all classes and field studies to receive full credit. Your final grade will be affected, adversely, by unexcused absences and lack of participation. Your participation grade will be reduced by 10 points (over 100) for every unexcused absence.
  • Classroom etiquette includes being respectful of other opinions, listening to others and entering a dialogue in a constructive manner.
  • You are expected to ask relevant questions in regards to the material covered.
  • Excuses for any emergency absences must be given beforehand. It is the responsibility of the student to make up any missed coursework.

Evaluation

To be eligible for a passing grade in this class, all of the assigned work must be completed by the set deadline.

Grading

Active participation: Includes attendance, preparation for lectures and other sessions, active participation in learning activities, class discussions, group work and problem solving. It also includes active participation during field studies and presentation of reflections on how they are related and relevant within the context of the course.

Problem Sets:  Homework problems will be posted on Canvas. Students are allowed to work in groups to complete their homework. A pdf scan or clear photo of their work must be submitted on Canvas.

Reading Assignment: Reading assignments will be given from the textbook and ancillary texts. Students are expected to make comments or well-formed questions throughout each reading assignment. 

Quizzes: Short quizzes that cover specific modules of the course will be posted on Canvas. You are expected to work on your own.

Final Exam: At the end of the semester, you will take an exam that covers all topics from the course. The exam will  be open for 24 hours. You are expected to work on your own. Once you start taking the exam, you will have 2 hours to complete it. You should provide final answers of problems on Canvas, and upload a pdf scan or clear photo of your work.

Active participation

10%

Reading Assignments

15%
Problem Sets

15%
Quizzes

40%

Final exam

20%

 

DIS Academic Regulations

Please make sure to read the Academic Regulations on the DIS website. There you will find regulations on:

Course Summary:

Course Summary
Date Details Due