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ENGINEERING THERMODYNAMICS (2131905) TOPIC : CARNOT VAPOR POWER CYCLE BRANCH : MECHANICAL ENGINEERING.

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Presentation on theme: "ENGINEERING THERMODYNAMICS (2131905) TOPIC : CARNOT VAPOR POWER CYCLE BRANCH : MECHANICAL ENGINEERING."— Presentation transcript:

1 ENGINEERING THERMODYNAMICS (2131905) TOPIC : CARNOT VAPOR POWER CYCLE BRANCH : MECHANICAL ENGINEERING

2 Prepared By 130460119026= PRASHANT DHOBI Guided By Prof. 1. Vinay Verma 2. Hiren M. Patel 3. Vishvash Patel

3 3 We consider power cycles where the working fluid undergoes a phase change. The best example of this cycle is the steam power cycle where water (steam) is the working fluid. Carnot Vapor Cycle

4 4 The heat engine may be composed of the following components. The working fluid, steam (water), undergoes a thermodynamic cycle from 1-2-3-4-1. The cycle is shown on the following T-s diagram.

5 5 The thermal efficiency of this cycle is given as Note the effect of T H and T L on  th, Carnot. The larger the T H the larger the  th, Carnot The smaller the T L the larger the  th, Carnot

6 6 To increase the thermal efficiency in any power cycle, we try to increase the maximum temperature at which heat is added. Reasons why the Carnot cycle is not used: Pumping process 1-2 requires the pumping of a mixture of saturated liquid and saturated vapor at state 1 and the delivery of a saturated liquid at state 2. To superheat the steam to take advantage of a higher temperature, elaborate controls are required to keep T H constant while the steam expands and does work. To resolve the difficulties associated with the Carnot cycle, the Rankine cycle was devised.

7 7 THANK YOU

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