Fluid mechanics MFKGT710005 MSc in Petroleum Engineering Full time course SUBJECT-MATTER COMMUNICATIONS DOSSIER UNIVERSITY OF MISKOLC FACULTY OF EARTH SCIENCE AND ENGINEERING INSTITUTE OF PETROLEUM AND NATURAL GAS Miskolc, 2018/2019. academic year II. semester
CONTENT Subjects data sheet Course schedule Test sample Test sample answer Exam readiness topics 2
SUBJECTS DATA SHEET Course Title: Fluid mechanics Instructor: Dr. Anikó Nóra TÓTH, associate professor László KIS, assistant lecturer Position in curriculum* (which semester): 2 (1) No. of contact hours per week (lecture + seminar): 3+0 Code: MFKGT710005 Responsible department/institute: DNGE/IPNG (GMTSZ/KFGI) Compulsory/Elective: C Pre-requisites (if any): no Type of Assessment (examination / practical mark / other): examination Credits: 3 Course: full time Course Description: This class provides students with an introduction to principal concepts and methods of fluid mechanics. Topics covered in the course include pressure, hydrostatics, and buoyancy; open systems and control volume analysis; mass conservation and momentum conservation for moving fluids; viscous fluid flows, flow through pipes; dimensional analysis; boundary layers, and lift and drag on objects. Students will work to formulate the models necessary to study, analyze, and design fluid systems through the application of these concepts, and to develop the problem-solving skills essential to good engineering practice of fluid mechanics in practical applications. Education method: Lectures with ppt presentation, laboratory exercises. The students must complete several stand-alone simulation tasks (homework) at home during the semester that makes a relevant part of the course grading. Knowledge: T2, T3, T6, T7, T8, T9, T10 Ability: K1, K4, K5, K6, K7, K8, K9, K10, K11 Attitude: - Autonomy and responsibility: F1, F2, F3, F4, F5, F6, F7 Assessment and grading: Students will be assessed with using the following elements. Attendance: 5 % Homework 10 % Short quizzes 10 % Midterm exam 40 % Final exam 35 % Total 100% Grading scale: % value Grade 90-100% 5 (excellent) 80 89% 4 (good) 70-79% 3 (satisfactory) 60-69% 2 (pass) 0-59% 1 (failed) 3 Compulsory or recommended literature resources: E. Bobok: Fluid Mechanics for Petroleum Engineers. Elsevier, Amsterdam, London, New York, Tokyo, 1993. ISBN: 10: 0-444-98668-5 V. L. Streeter, E. B. Wylie, K. W. Bedford: Fluid Mechanics. WCB/McGraw-Hill 1998, ISBN 0-07- 062537-9 R. Bird, W. Stewart, E. Lightfoot: Transport Phenomena. John Wiley and Sons, New York, 2007. ISBN: 978-0-470-11539-8 Bobok E.: Fluid Mechanics. 2013. Streeter W. et. al: Fluid Mechanics, Auckland: McGraw-Hill, 1983.
COURSE SCHEDULE Date Topic 2019.02.12 Kinematics 2019.02.19 Conservation of mass 2019.02.26 Balance Equations of momentum 2019.03.05 Perfect Fluid Flow 2019.03.12 Euler s equation 2019.03.19 Bernoulli s equation. 2019.03.26 Elements of gas dynamics. 2019.04.02 Test writing 2019.04.09 Bernoulli equation with friction 2019.04.16 Laminar and turbulent flow in pipes. 2019.04.23 Determination of pressure losses 2019.04.30 Moody s diagram 2019.05.07 Pressure losses in gas transporting pipe-lines. Non-isothermal losses in transporting pipe-lines 2019.05.14 Bernoulli equation with friction. 4
Test Sample Miskolci Egyetem Gázmérnöki Intézeti Tanszék 3515 Miskolc Egyetemváros Tel.: +36 46 565 078 E-mail: gastitkar@kfgi.uni-miskolc.hu Web: www.gas.uni-miskolc.hu 0-59 % (elégtelen) 60-69 % (elégséges) 70-79 % (közepes) 80-89 % (jó) 90-100 % (jeles) NÉV: TEST FOR FLUID MECHANICS 5
TEST SAMPLE ANSWER 6
COURSE TOPICS TO BE PREPARED TO THE EXAM 1. Fluid Mechanics Basic Equations Flow Problem Equations 2. Properties of Laminar and Turbulent Flows Laminar and Turbulent Flows 3. Steady Incompressible Laminar Flow in a Cylindrical Pipe Laminar Flow in a Cylindrical Pipe 4. Turbulent Flow through Pipes Turbulent Flow through Pipes 5. Head Loss in Straight Cylindrical Pipes Determination of Head Loss for a Laminar Flow 6. Determination of Head Loss for a Turbulent Flow 7. Head Losses Resulting from Fittings Head Losses for Flows through Pipes 8. Pressure Loss of a Low Velocity Gas Flow Pressure Loss of a Low Velocity Gas Flow 9. Flow in Pipes with Mechanical Energy Addition Flow in Pipes 10. Flow in Pipes with Heat Exchange Flow in Pipes with Heat Exchange 11. Exercises 12. Pressure Waves in One-Dimensional Pipe Flow Pressure Waves in One-Dimensional Pipe Flow 13. High Velocity Gas Flow in Pipes With Friction High Velocity Gas Flow in Pipes With Friction 7 Dr. Anikó Nóra TÓTH associate professor László KIS assistant lecturer Miskolc, 11 February 2019.