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Open Education Resources (OER): Introduction to Engineering Thermodynamics
Acknowledgements
Acknowledgements
Getting Started
Getting Started: Introduction to Jupyter and Python!
Basic operations inside Jupyter
Defining variables: Properties of Ideal Gases as use case
Modules
1. Basic Concepts and Definitions
1.1 Pressure in a Tank
1.2 Density of a Gas
1.3 Energy in a Moving Vehicle
1.4 Enthalpy of a Steam
1.5 Quality of a Vapor Mixture
1.6 Compressed Liquid Approximation
1.7 Conversion of Temperature
1.8 Specific Entropy Calculation
Chapter 1
Chapter 1
Chapter 1
Chapter 1
2. Thermodynamic Properties of a Pure Substance
2.1 Thermodynamic properties of Water
2.2 Thermodynamic properties of Ammonia
2.3 Thermodynamic properties of R-134a
2.4 Piston-cylinder: Isobaric process
2.5 Piston-cylinder: Isobaric- Isochoric process
2.6: Weighted Piston
2.7: Weighted Piston and Pressed Spring
2.8: Internal Energy in a Rigid Container
2.9: Saturated Water in a Rigid Tank
2.10: Water in Two Tanks
Chapter 2
Chapter 2
2.13: Air in Lungs
Chapter 2
Chapter 2
3. Ideal and Real Gases
3.1 Ideal gas law: Air
3.2 Thermo-mechanical Equilibrium: Partitions in a Box
3.3 Piston-cylinder system for Air
3.4 Isobaric-Isochoric process: Nitrogen as Ideal gas
3.5 Lee - Kesler Compressibility factor
3.6 Ideal gas assumption for Water
3.7: Validating Ideal Gas Assumption
3.8: Pressurized Cylinder: Carbon dioxide
3.9: Can Crush
3.10: Whistle Kettle
Chapter 3
4. The First Law of Thermodynamics for Closed Systems
Rigid container: Polytropic process
4.1: Piston-cylinder: isothermal expansion
4.2 Isochoric Process for a Gas
4.3 Adiabatic Compression of an Ideal Gas
4.4 Heat Transfer in a Rigid Container
4.5 Helium in a Spring-Loaded Cylinder
4.6 Isothermal Expansion of Nitrogen
4.7 Adiabatic Compression in a Rigid Container
4.8 Linear interpolation for Internal energy of Superheated water
4.9 Reference States in Thermodynamics
4.10: Comparison of work done in different processes
4.11: Polytropic Tire Deflation
4.12: P-v diagram for Polytropic air
5. The First Law of Thermodynamics for a Control Volume
5.1: Energy balance for Stream in Control Volume
5.2 Piston-cylinder: Carbon dioxide
5.3: Air Compressor and Turbine
5.4 P-h diagram for R-134a refrigerant
5.5 Refrigeration cycle: R134a
5.6 Refrigeration cycle: R134a
5.7 Refrigeration cycle: Water flow-rate
Chapter 5
5.8 Nozzle: Hydrogen gas
Chapter 5
Chapter 5
Chapter 5
5.9: Reheat Cycle
Chapter 5
6. Entropy and the Second Law of Thermodynamics
6.1 Multi-evaporator refrigeration system
6.2 Hot water in an open container
6.3 Rankine Cycle
6.4 Refrigeration/ heat pump system
6.5 Heat engine and refrigeration cycle
6.6 T-s diagram for Water
6.7 Entropy change in Rigid tank
6.9 Entropy generation: steam in Piston-cyclinder
6.9 Entropy generation: Polytropic compression of Air
6.10: Air in rigid tank: two compartments
6.11 Second Law for an Open Turbine
6.12: Second Law for a Refrigration Cycle
6.13 Entropy in a heated rigid tank
6.14 Entropy Generation for a Steam Cycle
6.15 Detailed Entropy Generation for a Steam Cycle
6.16 Multilevel Carnot Heat Engine
Chapter 6.16
Chapter 6
Chapter 6
Interactive Diagrams
Property Diagrams
P-h diagrams
P-v diagrams
T-s diagrams
T-v diagrams
Repository
Open issue
Index