Ideal Gas Equation and COMPRESSIBILITY Factor in 11 Minutes!

Описание: Ideal Gas Equation
Compressibility Factor Z
Critical Pressure
Critical Temperature
Reduced Pressure
Reduced Temperature
Reduced Volume
Universal Gas Constant, R bar

0:00 Property Tables Summary
0:26 Equations of State
0:50 Ideal Gas Equation "Derivation"
2:01 Universal Gas Constant
3:12 Molar Mass
3:52 Gas-Specific Constant & Molar Mass
4:39 Water as Ideal Gas?
5:27 Compressibility Factor
6:18 Critical Point, Temperature, and Pressure
6:39 Reduced Pressure, Temperature, and Volume
7:11 Compressibility Charts
7:46 When You Have Reduced Volume
8:21 Example for P and T Z-Chart

Example 1:    • Thermal Equilibrium Using Ideal Gas Equati...  
Example 2:    • COMPRESSIBILITY factor Z, Using P and v in...  
Example 3:    • IDEAL GAS Inside Rigid Tank - State 1 to S...  


Previous Lecture:
9. Compressed Liquid Properties:    • Thermodynamics COMPRESSED Liquid Propertie...  

Next Lecture:
11. Specific Heats: coming soon

_______________________________________

Other Thermodynamics Lectures:

1. Thermodynamics Intro and Units Review:    • THERMODYNAMICS Basic Units and Pressure Co...  
2. Zeroth Law of Thermodynamics:    • ZEROTH LAW of Thermodynamics & Temperature...  
3. Closed vs. Open Systems & Intensive vs. Extensive Properties:    • CONTROL VOLUMES - Closed vs. Open - Extens...  
4. First Law and Energy Types:    • Energy Conservation Equation & FIRST LAW o...  
5. Efficiency in Thermodynamic Systems:    • EFFICIENCY of Thermodynamic Systems in 10 ...  
6. Five Regions of T-v Diagrams:    • T-v Diagrams and PROPERTY TABLES for Therm...  
7. Interpolating and Quality Derivation:    • INTERPOLATION for Thermodynamics and Mixtu...  
8. Enthalpy and Internal Energy:    • ENTHALPY and INTERNAL ENERGY in 12 Minutes!  
9. Compressed Liquid Properties:    • Thermodynamics COMPRESSED Liquid Propertie...  
10. Ideal Gas and Compressibility Factor:    • Ideal Gas Equation and COMPRESSIBILITY Fac...  
11. Specific Heats:    • Thermodynamics SPECIFIC HEATS - cv & cp - ...  
12. Specific Heat Relationships of Ideal Gases and Incompressible Substances:    • Specific Heat and Energy Changes for INCOM...  
13. Polytropic Process Work:    • Work Expressions for POLYTROPIC Processes ...  
14. Mass and Volumetric Flow Rate:    • Volumetric and MASS FLOW RATES for Thermod...  
15. Flow Work and Energy Conservation in Open Systems:    • FLOW WORK & Energy Conservation in Open Sy...  
16. Pipe Flow, Nozzles, Diffusers, and Throttling Devices:    • Pipe Flow, Nozzles, Diffusers, and Throttl...  
17. Turbines, Compressors, and Pumps:    • Thermodynamics - Turbines, Compressors, an...  
18. Mixing Chambers and Heat Exchangers:    • Heat Exchangers and Mixing Chambers - THER...  
19. Transient Systems:
20. Second Law Intro and Power Cycles:    • 2nd Law Intro and POWER CYCLES in 10 Minutes!  
21. Refrigerators and Heat Pumps:    • REFRIGERATION and Heat Pump Cycles in 10 M...  
22. Carnot Cycles and Reversible Processes:    • Reversible Processes and CARNOT CYCLE in 1...  
23. Entropy as a Thermodynamic Property:    • Thermodynamics - ENTROPY as a Property in ...  
24. Reference Entropy and Specific Heats:    • REFERENCE ENTROPY and Specific Heats in 12...  
25. Isentropic Efficiency:    • Turbines, Compressors, and Pumps - ISENTRO...  
26. Brayton Cycle:    • Ideal BRAYTON CYCLE Explained in 11 Minutes!  
27. Intercooling, Reheating, and Regenerators:    • Regeneration, Intercooling, and Reheating ...  
28. Otto Cycle:
29. Standard Diesel Cycle:
30. Rankine Cycle:
.
.
.
.


________________________________________

Other Engineering Courses (Playlists):
   / lessboringlectures  

Statics:    • Statics: Engineering Mechanics  

Mechanics of Materials:    • Mechanics of Materials  

Machine Design:    • Mechanical Engineering Design I  

SolidWorks (CAD):    • SolidWorks (CAD)  

Fluid Mechanics:    • Fluid Mechanics