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Course
Pro-forma
Bachelor of Engineering (Computer Aided Design & Manufacturing)
Code
KCEP1111
Title
Thermodynamics
Pre-requisite
None
Student Learning Time (SLT)
120 hours
Credit
3
Learning Outcomes
1.
Interpret heat, work, thermal effect and the difference
among various forms of energy.
2.
Explain the process of energy transfer (from various forms of
energy, heat and work) for engineering systems using the
first law of thermodynamics.
3.
Analyze engineering thermodynamics systems using the
equation of energy conservation
4.
Evaluate the dependent/ independent concept and the
reversible process using second law of thermodynamics
5.
Analyze the simple thermal engine cycle to estimate the
thermal efficiency in heat and work.
Synopsis
Basic concept: System, model and law, heat and work transfer
concept. First Thermodynamics Law: State of simple substances,
equation of state, energy as work and heat, energy principle and
energy conservation. Usage for non-steady and steady flow
process. Modes of heat transfer and the second law of
Thermodynamics Law: Entropy, reversible and irreversible
process, entropy as a function of state, some consequences of
the second law, engineering problem considering the entropy.
Assessment
40 % Continuous Assessments
60 % Final Examination
References
1.
Yunus A. Cengel Michael A. Boles Thermodynamics: An
Engineering Approach, 4/e McGraw-Hill
2.
M.J. Moran and H.N. Shapiro, Fundamentals of Engineering
Thermodynamics, 5/e, Wiley, 2004
3.
Fundamentals of Thermal-Fluid Sciences by Yunus A. Cengel
and Robert H. Tuner (Mc Graw Hill), 2008
4.
Engineering Thermodynamics, W.C. Reynold, H.C. Perkins,
(Mc. Graw Hill).
Soft Skills
Critical Thinking & Problem Solving Skills (CT1, CT2, CT3)
Team Work Skills (TS1, TS2)