Comprehensive Guide to Engineering Thermodynamics Principles
Unlock the Mysteries of Thermodynamics: From Fundamental Laws to Real-World Applications! Dive into the science behind energy transfer, explore key concepts, and master the efficiency of mechanical systems with "Engineering Thermodynamics.
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395 learners
What you'll learn
Understand the fundamental laws and principles of thermodynamics.
Apply energy balance concepts to various thermodynamic systems.
Analyze the efficiency and processes of power and refrigeration cycles.
Evaluate the implications of the second law of thermodynamics and entropy.
This course includes
20.3 hours of video
Certificate of completion
Access on mobile and TV
Course content
1 modules
• 58 lessons
• 20.3 hours of video
Comprehensive Guide to Engineering Thermodynamics Principles
58 lessons
• 20.3 hours
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Fundamental laws of nature, system definitions and applications17:55
Thermodynamic property, state, equilibrium and process15:41
Temperature scale and pressure27:31
Macroscopic and microscopic forms of energy19:51
Different forms of work, energy transfer and sign convention11:43
First law of thermodynamics and energy balance16:17
Efficiency of mechanical and electrical devices23:50
Examples on basic concept and energy balance24:26
Phase change of a pure substance18:30
Property diagrams of pure substances24:29
Thermodynamic properties of a pure substance from a property table22:34
Thermodynamic properties of a pure substance12:41
Equations of state and compressibility chart20:21
Examples on properties of pure substances30:53
Quasi equilibrium, moving boundary work16:17
Polytropic process11:25
Energy analysis of closed system and unrestrained expansion22:48
Internal energy, enthalpy, and specific heats of ideal gas20:21
Internal energy, enthalpy, and specific heats of solids and liquids21:34
Examples on energy balance for closed systems and moving boundary work41:01
Conservation of mass and steady flow processes21:17
Flow work and energy of flowing fluid19:50
Energy balance for steady flow devices23:56
Throttling valve, mixing chamber and heat exchanger18:55
Energy analysis of steady and unsteady flow devices15:43
Examples on mass and energy analysis of open systems26:07
Second law of thermodynamics, heat engine and cyclic devices17:28
COP of refrigerator and heat pump, second law statements12:33
Perpetual motion machines, reversible and irreversible processes, Carnot cycle14:56
Carnot principles, thermodynamic temperature scale, Carnot HE and HP24:30
Examples on second law of thermodynamics21:48
Clausius inequality, application of second law20:33
Entropy, increase in entropy principle, isentropic process20:58
Change in entropy of solids, liquids and ideal gases25:08
Reversible flow work, multistage compressor, efficiency of pump and compressors24:45
Entropy balance in closed system and control volume15:36
Examples on entropy change in a system28:44
Exergy and second law efficiency21:04
Exergy of a fixed mass and flowing stream19:02
Exergy transfer due to heat, mass and work, exergy destruction21:09
Exergy balance and second law efficiency for closed systems and steady flow devices17:47
Examples related to exergy change and exergy destruction48:40
Gas power cycles and air-standard assumptions16:54
An overview of reciprocating engines and otto cycle13:15
Analysis of Diesel cycle06:44
Analysis of Brayton cycle25:35
Examples on gas power cycles such as Otto, Diesel and Brayton28:22
Rankin and Carnot vapour power cycles16:19
Ideal regenerative Rankin cycle and combined gas-vapour cycle25:17
Refrigeration cycles21:52
Examples on vapour power cycles23:56
Thermodynamic property relations: Gibbs equation, Mnemonic diagrams and reciprocity relations21:20
Thermodynamic property relations: Clapeyron equation and Maxwell relations12:59
Thermodynamic property relations: Joule-Thomson coefficient and cyclic relations23:44
Combustion and conservation of mass in a chemical reaction16:08
Energy balance for reacting systems17:12
Enthalpy of formation and combustion, adiabatic flame temperature27:57
Examples on property relations and reaction thermodynamics25:50
