Answered: Q4: Steam at 100 kPa and 10°C steadily… | bartleby

Related questions

Question

Q4: Steam at 100 kPa and 10°C steadily enters
a nozzle whose inlet area is 0.4 m? with a the
internal energy of 280 kJ/ kg and velocity of
150 m/s and leaves the nozzle with a velocity
P 100kPa 1
T = 10°C
A1= 0.4 m2
Steam
that is very small (assume V-0 m/s), take R
0.287 kPa.m/kg.K. Determine: (a) the mass
flow rate of the steam and (b) the internal
energy of the steam leaving the nozzle.
(25 Degree)

Expert Solution

Step by step

Solved in 2 steps

SEE SOLUTION Check out a sample Q&A here

Blurred answer

Similar questions

P₁ P3 Р V. T₁ 2 T₂ 3 T₁ V V. A heat engine consists of a heat source that causes a monatomic gas to expand, pushing against a piston, there by doing work. The gas begins at a pressure of p₁-300 kPa, a volume of V₁=150 cm³, and room temperature, T₁= 20 °C. On reaching a volume of V₂=450 cm³, the piston is locked in place, and the heat source is removed. At this point the gas cools back to room temperature. Finally, the piston is unlocked and used to isothermally compress the gas back to its initial state. The cycle is shown on the pV-diagram in the figure. Molar heat capacity at constant pressure for monatomic ideal gas is Cp = Cv+ R = 5R/2 where the universal gas constant is R = 8.314 J/mol K) Determine the work done on the gas in the process 2-3. Express your answer in J.
Q8: From the P-V diagrams below find the network for the cycle process of 1 mole gas at 27°C. A P (105Pa) 200 kPa P B 100 kPa 0.05m³ Isotherm 0.1m³ V 9.00 6.00 3.00 2 1 V (m³) 2.00 4.00 6.00
3-
A 1.70-mol sample of hydrogen gas is heated at constant pressure from 302 K to 426 K. (a) Calculate the energy transferred to the gas by heat. kJ (b) Calculate the increase in its internal energy. k] (c) Calculate the work done on the gas. kJ
10-