Air at 200 kPa, 52°C, and a velocity of 355 m/s enters an insulated duct of varying cross-sectional area. The air exits at 100 kPa, 82°C. At the inlet, the cross-sectional area is 11.57 cm². Assuming...

Air at 200 kPa, 52°C, and a velocity of 355 m/s enters an insulated duct of varying cross-sectional area. The air exits at 100 kPa, 82°C.<br>At the inlet, the cross-sectional area is 11.57 cm².<br>Assuming the ideal gas model for the air, determine:<br>(a) the exit velocity, in m/s.<br>(b) the rate of entropy production within the duct, in kW/K.<br>Part A<br>Determine the exit velocity, in m/s.<br>V2 =<br>i<br>m/s<br>Save for Later<br>Attempts: 0 of 1 used<br>Submit Answer<br>Part B<br>The parts of this question must be completed in order. This part will be available when you complete the part above.<br>

Extracted text: Air at 200 kPa, 52°C, and a velocity of 355 m/s enters an insulated duct of varying cross-sectional area. The air exits at 100 kPa, 82°C. At the inlet, the cross-sectional area is 11.57 cm². Assuming the ideal gas model for the air, determine: (a) the exit velocity, in m/s. (b) the rate of entropy production within the duct, in kW/K. Part A Determine the exit velocity, in m/s. V2 = i m/s Save for Later Attempts: 0 of 1 used Submit Answer Part B The parts of this question must be completed in order. This part will be available when you complete the part above.

Jun 11, 2022

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Air at 200 kPa, 52°C, and a velocity of 355 m/s enters an insulated duct of varying cross-sectional area. The air exits at 100 kPa, 82°C. At the inlet, the cross-sectional area is 11.57 cm². Assuming...

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