Engineering Thermodynamics
Engineering Thermodynamics. Instructor: Dr. Jayant K. Singh, Department of Chemical Engineering, IIT Kanpur. This course provides an introduction to the most powerful engineering principles -Thermodynamics: the science of energy and its transformation from one form to another form. The subject is widely applicable in several branches of engineering and science. The objective of this course is to introduce systematic different tools needed to analyze energy systems from various daily lives to large scale engineering applications. More specifically, we will cover the topics of mass and energy conservation principles; first law analysis of closed and open systems; understanding second law of thermodynamics and entropy; exergy; properties of pure substances; power generation and refrigeration on thermodynamic cycles; thermodynamic relation, combustion and reaction.
(from nptel.ac.in )
Lecture 54 - Thermodynamic Property Relations: Joule-Thomson Coefficient, Cyclic Relations
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Introduction to Energy and Energy Transfer
Lecture 01 - Fundamental Laws of Nature, System Definitions and Applications
Lecture 02 - Thermodynamic Property, State, Equilibrium, Process
Lecture 03 - Temperature Scale and Pressure
Lecture 04 - Macroscopic and Microscopic Forms of Energy
Lecture 05 - Different Forms of Work, Energy Transfer and Sign Convention
Lecture 06 - First Law of Thermodynamics and Energy Balance
Lecture 07 - Efficiency of Mechanical and Electrical Devices
Lecture 08 - Examples on Basic Concepts and Energy Balance
Properties of Pure Substances
Lecture 09 - Phase Change of a Pure Substance
Lecture 10 - Property Diagrams of Pure Substances
Lecture 11 - Thermodynamic Properties of a Pure Substance from a Property Table
Lecture 12 - Thermodynamic Properties of a Pure Substance
Lecture 13 - Equations of State and Compressibility Chart
Lecture 14 - Example Problems on Properties of Pure Substances
Energy Analysis of Closed System
Lecture 15 - Quasi-equilibrium, Moving Boundary Work
Lecture 16 - Polytropic Process
Lecture 17 - Energy Analysis of Closed System, Unrestrained Expansion
Lecture 18 - Internal Energy, Enthalpy, and Specific Heats of Ideal Gas
Lecture 19 - Internal Energy, Enthalpy, and Specific Heats of Solids and Liquids
Lecture 20 - Examples on Energy Balance for Closed Systems and Moving Boundary Work
Mass and Energy Analysis of Open Systems
Lecture 21 - Conservation of Mass and Steady Flow Processes
Lecture 22 - Flow Work and Energy of Flowing Fluid
Lecture 23 - Energy Balance for Steady Flow Devices
Lecture 24 - Throttling Valve, Mixing Chamber and Heat Exchanger
Lecture 25 - Energy Analysis of Steady and Unsteady Flow Devices
Lecture 26 - Examples on Energy and Mass Balance for Open Systems
The Second Law of Thermodynamics and Entropy
Lecture 27 - Second Law of Thermodynamics, Heat Engine and Cyclic Devices
Lecture 28 - COP of Refrigerator and Heat Pump, Second Law Statements
Lecture 29 - Perpetual Motion Machines, Reversible and Irreversible Processes, Carnot Cycle
Lecture 30 - Carnot Principles, Thermodynamic Temperature Scale, Carnot HE and HP
Lecture 31 - Examples on the Second Law of Thermodynamics
Lecture 32 - Clausius Inequality, Applications of the Second Law of Thermodynamics
Lecture 33 - Entropy, Increase in Entropy Principle, Isentropic Process
Lecture 34 - Change in Entropy of Solids, Liquids, and Ideal Gases
Lecture 35 - Reversible Flow Work, Multistage Compressor, Efficiency of Pump and Compressors
Lecture 36 - Entropy Balance in Closed System and Control Volume
Lecture 37 - Examples related to Entropy Change in a System
Exergy Analysis
Lecture 38 - Exergy and Second Law Efficiency
Lecture 39 - Exergy of a Fixed Mass and Flowing Stream
Lecture 40 - Exergy Transfer due to Heat, Mass and Work, Exergy Destruction
Lecture 41 - Exergy Balance and Second Law Efficiency for Closed Systems and Steady Flow Devices
Lecture 42 - Examples related to Exergy Change and Exergy Destruction
Power and Refrigeration Cycles
Lecture 43 - Gas Power Cycle, Air Standard Assumptions, Value of Carnot Cycle in Engineering
Lecture 44 - An Overview of Reciprocating Engine Otto Cycle
Lecture 45 - Analysis of Diesel Cycle
Lecture 46 - Analysis of Brayton Cycle
Lecture 47 - Examples on Gas Power Cycles such as Otto Diesel and Brayton
Lecture 48 - Rankine and Carnot Vapor Power Cycles
Lecture 49 - Ideal Regenerative Rankine Cycle, Cogeneration, Combined Gas Vapor Cycle
Lecture 50 - Refrigeration Cycles
Lecture 51 - Examples on Vapour Power Cycles
Thermodynamic Potentials and I Law Application to Chemically Reacting Systems
Lecture 52 - Thermodynamic Property Relations: Gibbs Equation, Mnemonic Diagrams and Reciprocity Relations
Lecture 53 - Thermodynamic Property Relations: Clapeyron Equation and Maxwell Relation
Lecture 54 - Thermodynamic Property Relations: Joule-Thomson Coefficient, Cyclic Relations
Lecture 55 - Combustion and Conservation of Mass in a Chemical Reaction
Lecture 56 - Energy Balances for Reacting Systems
Lecture 57 - Enthalpy of Formation and Combustion, Adiabatic Flame Temperature
Lecture 58 - Examples on Reaction Thermodynamics and Property Relations