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Lec 13: Stirling & Ericsson cycles
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Classroom Contents
Applied Thermodynamics for Engineers
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- 1 Applied Thermodynamics For Engineers [Introduction Video]
- 2 Lec 1: Overview of thermodynamic system & state
- 3 Lec 2: First & second laws of thermodynamics
- 4 Lec 3: Concept of entropy & entropy generation
- 5 Lec 4: Concept of exergy & exergy destruction
- 6 Lec 5: Thermodynamic potentials & Maxwell relations
- 7 Lec 6: Generalized relations for entropy & specific heats
- 8 Lec 7: Joule-Thomson coefficient & Clapeyron equation
- 9 Lec 8: Liquid-vapor phase-change process
- 10 Lec 9: Use of property tables
- 11 Lec 10: Equations-of-state & Compressibility factor
- 12 Lec 11: Ideal cycles for reciprocating engines
- 13 Lec 12: Otto, Diesel & Dual combustion cycles
- 14 Lec 13: Stirling & Ericsson cycles
- 15 Lec 14: Fuel-air cycle
- 16 Lec 15: Numerical exercise on Fuel-air cycles
- 17 Lec 16: Losses in actual cycle & valve-timing diagram
- 18 Lec 17: Ideal Brayton cycle
- 19 Lec 18: Intercooling & reheating in Brayton cycle
- 20 Lec 19: Regeneration in Brayton cycle
- 21 Lec 20: Ideal Rankine cycle
- 22 Lec 21: mprovements & modifications in Rankine cycle
- 23 Lec 22: Regenerative Rankine cycle
- 24 Lec 23: Binary vapor power cycle
- 25 Lec 24: Combined gas-steam power plant
- 26 Lec 25: Different arrangments in combined cycles
- 27 Lec 26: Vapor compression refrigeration cycle
- 28 Lec 27: SSS cycles & refrigerants
- 29 Lec 28: Modifications in VCR systems
- 30 Lec 29: Vapor absorption refrigeration cycle
- 31 Lec 30: P-v-T behavior of gas mixtures
- 32 Lec 31: Numerical examples
- 33 Lec 32: Properties of moist air
- 34 Lec 33: Psychrometric chart & various psychrometric processes
- 35 Lec 34: Sensible heat factor & bypass factor
- 36 Lec 35: Theoretical & actual combustion process
- 37 Lec 36: Thermodynamic analyses of reacting systems