Thermal Engineering\u2013II syllabus for JNTUH B.Tech III year II sem is covered here. This gives the details about credits, number of hours and other details along with reference books for the course.<\/p>\n
B.Tech. III Year II Sem. \u00a0 L\/T\/P\/C
\nCourse Code:ME601PC \u00a0 \u00a0 \u00a0 4\/1\/0\/4
\nNote: Steam Table book Permitted.
\nPre-requisite: Thermodynamics<\/p>\n
Course Objective:<\/strong> To apply the laws of Thermodynamics to analyze steam and gas turbine\u00a0cycles and to perform analysis of the major components of steam and gas turbine\u00a0plants and their applications.<\/p>\n Course Outcomes:<\/strong> At the end of the course, the student should be able to<\/p>\n UNIT \u2013 I:<\/strong>\u00a0Steam Power Plant: Rankine cycle – Schematic layout, Thermodynamic Analysis, Concept\u00a0of Mean Temperature of Heat addition, Methods to improve cycle performance \u2013\u00a0Regeneration & reheating.\u00a0Boilers \u2013 Classification \u2013 Working principles with sketches including H.P.Boilers \u2013\u00a0Mountings and Accessories \u2013 Working principles- Boiler horse power, Equivalent\u00a0Evaporation, Efficiency and Heat balance \u2013 Draught- Classification \u2013 Height of chimney for\u00a0given draught and discharge- Condition for maximum discharge- Efficiency of chimney.<\/p>\n UNIT \u2013 II:<\/strong> \u00a0Steam Nozzles : Stagnation Properties- Function of nozzle \u2013 Applications and Types- Flow\u00a0through nozzles- Thermodynamic analysis \u2013 Assumptions -Velocity of nozzle at exit-Ideal\u00a0and actual expansion in nozzle- Velocity coefficient- Condition for maximum discharge Critical\u00a0pressure ratio- Criteria to decide nozzle shape- Super saturated flow, its effects,\u00a0Degree of super saturation and Degree of under cooling – Wilson line.<\/p>\n UNIT \u2013 III:<\/strong>\u00a0Steam Turbines: Classification \u2013 Impulse turbine; Mechanical details \u2013 Velocity diagram \u2013\u00a0Effect of friction \u2013 Power developed, Axial thrust, Blade or diagram efficiency \u2013 Condition\u00a0for maximum efficiency. De-Laval Turbine – its features- Methods to reduce rotor speed Velocity\u00a0compounding and Pressure compounding- Velocity and Pressure variation along the\u00a0flow \u2013 Combined velocity diagram for a velocity compounded impulse turbine.\u00a0Reaction Turbine: Mechanical details \u2013 Principle of operation, Thermodynamic analysis of\u00a0a stage, Degree of reaction \u2013Velocity diagram \u2013 Parson\u2019s reaction turbine \u2013 Condition for\u00a0maximum efficiency.<\/p>\n\n