Module NameDownload

Sl.No Chapter Name MP4 Download Transcript Download
1Lec 1: Overview of thermodynamic system & stateDownloadPDF unavailable
2Lec 2: First & second laws of thermodynamicsDownloadPDF unavailable
3Lec 3: Concept of entropy & entropy generationDownloadPDF unavailable
4Lec 4: Concept of exergy & exergy destructionDownloadPDF unavailable
5Lec 5: Thermodynamic potentials & Maxwell relationsDownloadPDF unavailable
6Lec 6: Generalized relations for entropy & specific heatsDownloadPDF unavailable
7Lec 7: Joule-Thomson coefficient & Clapeyron equationDownloadPDF unavailable
8Lec 8: Liquid-vapor phase-change processDownloadPDF unavailable
9Lec 9: Use of property tablesDownloadPDF unavailable
10Lec 10: Equations-of-state & Compressibility factorDownloadPDF unavailable
11Lec 11: Ideal cycles for reciprocating enginesDownloadPDF unavailable
12Lec 12: Otto, Diesel & Dual combustion cyclesDownloadPDF unavailable
13Lec 13: Stirling & Ericsson cyclesDownloadPDF unavailable
14Lec 14: Fuel-air cycleDownloadPDF unavailable
15Lec 15: Numerical exercise on Fuel-air cyclesDownloadPDF unavailable
16Lec 16: Losses in actual cycle & valve-timing diagramDownloadPDF unavailable
17Lec 17: Ideal Brayton cycleDownloadPDF unavailable
18Lec 18: Intercooling & reheating in Brayton cycleDownloadPDF unavailable
19Lec 19: Regeneration in Brayton cycleDownloadPDF unavailable
20Lec 20: Ideal Rankine cycleDownloadPDF unavailable
21Lec 21: Improvements & modifications in Rankine cycleDownloadPDF unavailable
22Lec 22: Regenerative Rankine cycleDownloadPDF unavailable
23Lec 23: Binary vapor power cycleDownloadPDF unavailable
24Lec 24: Combined gas-steam power plantDownloadPDF unavailable
25Lec 25: Different arrangments in combined cyclesDownloadPDF unavailable