ENS202 Thermodynamics

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Course Code Course Title Weekly Hours* ECTS Weekly Class Schedule
T P
ENS202 Thermodynamics 3 2 6 Mon 11.00-12.50, Wed 10.00-10.50
Prerequisite MATH202, NS102 It is a prerequisite to
Lecturer Muhamed Hadziabdic Office Hours / Room / Phone
Tuesday:
11:00-14:00
Thursday:
12:00-14:00
A F1.31 - 033 957 212
E-mail mhadziabdic@ius.edu.ba
Assistant Mahir Hafizovic Assistant E-mail mahir.hafizovic@gmail.com
Course Objectives The course introduces basic concepts and principles of thermodynamics. Students will look and understand different systems, from household appliances to live organisms, through a prism of thermodynamics laws. Concept of energy, work and entropy will be connected to life and surrounding technologies.
Textbook Thermodynamics: An Engineering Approach 8th Edition by Yunus Cengel, and Michael Boles, Principles of Engineering Thermodynamics, John R. Resiel. Fundamentals of Engineering Thermodynamics Michael J. Moran, Howard N. Shapiro, Biological Thermodynamics, Donald T. Haynie, Thermodynamics: An engineering approach, Yunus Cengel
Learning Outcomes After successful  completion of the course, the student will be able to:
  1. Apply the ideal-gas equation of state in the solution of typical problems.
  2. Solve energy balance problems for closed (fixed mass) systems that involve heat and work interactions for general pure substances, ideal gases, and incompressible substances.
  3. Apply the steady-flow energy equation or the First Law of Thermodynamics to a system of thermodynamic components (heaters, coolers, pumps, turbines, pistons, etc.) to estimate required balances of heat, work and energy flow.
  4. Apply the second law of thermodynamics to cycles and cyclic devices.
  5. Calculate the entropy changes that take place during processes for pure substances, incompressible substances, and ideal gases.
Teaching Methods Class discussions with examples. Active tutorial sessions for engaged learning and continuous feedback on progress.
WEEK TOPIC REFERENCE
Week 1 Introduction to theromdynamics and energy
Week 2 Pressure, The Manometer, The Barometer and Atmospheric Pressure
Week 3 Energy Conversion and General Energy Analysis
Week 4 The First Law of Thermodynamics
Week 5 Properties of Pure Substances
Week 6 Properties of Pure Substances
Week 7 Energy Analysis of Closed Systems
Week 8 Midterm exam
Week 9 Energy Analysis of Closed Systems, Energy conservation in the living organisms
Week 10 Mass and Energy Analysis of Control Volumes
Week 11 Mass and Energy Analysis of Control Volumes
Week 12 The Second Law of Thermodynamics
Week 13 Entropy
Week 14 Gibbs free energy
Week 15 Review of Topics
Assessment Methods and Criteria Evaluation Tool Quantity Weight Alignment with LOs
Final Exam 1 40 1-5
Semester Evaluation Compenents
In-term Exam 1 30 1-3
Quiz 1 10 1-3, 4-5
Assignments 4 20 1-3, 4-5
***     ECTS Credit Calculation     ***
 Activity Hours Weeks Student Workload Hours Activity Hours Weeks Student Workload Hours
Lecture Hours 3 15 45 Home Study 3 14 42
Assignments 5 4 20 Assignments 5 4 20
Active Tutorials 2 15 30 Final Exam Study 8 1 8
        Total Workload Hours = 150
*T= Teaching, P= Practice ECTS Credit = 6
Course Academic Quality Assurance: Semester Student Survey Last Update Date: 19/03/2020
QR Code for https://ecampus.ius.edu.ba/course/ns102-physics

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