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THERMODYNAMIC ANALYSIS OF IC ENGINE Prepared by- Sudeesh kumar patel.

Published bysudeesh patel Modified over 7 years ago

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Presentation on theme: "THERMODYNAMIC ANALYSIS OF IC ENGINE Prepared by- Sudeesh kumar patel."— Presentation transcript:

1 THERMODYNAMIC ANALYSIS OF IC ENGINE Prepared by- Sudeesh kumar patel

2 INTRODUCTION An engine which generates motive power by the burning of petrol, oil, or other fuel with air inside the engine, the hot gases produced being used to drive a piston or do other work as they expand. Internal-combustion engine-

3 CLASSIFICATION OF INTERNAL- COMBUSTION ENGINE-

4 Process 1→ 2 Isentropic compression Process 2 → 3 Constant volume heat addition Process 3 → 4 Isentropic expansion Process 4 → 1 Constant volume heat rejection v 2 TC v 1 BC Q out Q in Air-Standard Otto cycle Compression ratio:

5 First Law Analysis of Otto Cycle 1→2 Isentropic Compression AIR 2→3 Constant Volume Heat Addition AIR Q in TC

6 3 → 4 Isentropic Expansion AIR 4 → 1 Constant Volume Heat Removal AIR Q out BC

7 Cycle thermal efficiency: Indicated mean effective pressure is : Net cycle work: First Law Analysis Parameters

8 Effect of Compression Ratio on Thermal Efficiency Effect of Specific Heat Ratio on Thermal Efficiency

9 Process 1→ 2 Isentropic compression Process 2 → 3 Constant pressure heat addition Process 3 → 4 Isentropic expansion Process 4 → 1 Constant volume heat rejection Air-Standard Diesel cycle Q in Q out Cut-off ratio: v 2 TC v 1 BC TC BC

10 For cold air-standard the above reduces to: Thermal Efficiency, Note the term in the square bracket is always larger than one so for the same compression ratio, r, the Diesel cycle has a lower thermal efficiency than the Otto cycle Note: CI needs higher r compared to SI to ignite fuel

11 Typical CI Engines 15 < r < 20 When r c (= v 3 /v 2 )→1 the Diesel cycle efficiency approaches the efficiency of the Otto cycle Thermal Efficiency Higher efficiency is obtained by adding less heat per cycle, Q in, → run engine at higher speed to get the same power.

12 For the same inlet conditions P 1, V 1 and the same compression ratio P 2 /P 1 : For the same inlet conditions P 1, V 1 and the same peak pressure P 3 : Diesel Dual Otto Diesel Dual Otto “x” →“2.5” P max T ma x PoPo PoPo Pressure, P Temperature, T Specific Volume Entropy

13 HEAT DISTRIBUTION IN INTERNAL COMBUSTION ENGINE

14 CONTACTS- ✕ Sudeesh kumar patel- Sudeesh.patel781@gmail.com

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