(a) Explanation The figure below shows the T - s diagram of the nozzle. Figure-(1) Write the expression for gas constant. R = R ¯ M (I) Here, universal gas constant is R ¯ , gas constant is R and the molecular mass is M . Write the expression for specific capacity. c p = k R ( k − 1 ) (II) Here, constant is c p and the other constant is k . Write the expression for velocity at point 2s. v 2 s = v 1 2 + 2 c p ( T 1 − T 2 ) (III) Here, velocity at point 2s is v 2 s , temperature at state 1 is T 1 and the temperature at state 2 is T 2 . Conclusion: Substitute 1.986 Btu / kmol ⋅ °R for R ¯ and 4.003 kmol / lb for M in Equation (I). R = 1.986 Btu / kmol ⋅ °R 4.003 kmol / lb = 0.4961279 Btu / lb ⋅ °R Substitute 0.4961279 Btu / lb ⋅ °R for R and 1.67 for k in Equation(II). c p = ( 0.4961279 Btu / lb ⋅ °R ) 1.67 ( 1 (b) To determine The isentropic nozzle efficiency. (c) To determine The rate of entropy production.

8th Edition

ISBN: 2818440116926

Author: MORAN

Publisher: WILEY CONS

See similar textbooks

Concept explainers

Work and Heat Transfer

It is generally related to thermal engineering which tells about the use, creation, conversion and transfer of heat energy between the systems. It is also considered that to transfer heat from one source to another, transfer of masses is also required. T…

Videos

Question

Chapter 6.13, Problem 156P

(a)

To determine

The velocity at nozzle exit.

(b)

To determine

The isentropic nozzle efficiency.

(c)

To determine

The rate of entropy production.

Expert Solution & Answer

Want to see the full answer?

Check out a sample textbook solution

See solution

Chapter 6.13, Problem 155P

Chapter 6.13, Problem 157P

Students have asked these similar questions

A converging elbow (see the figure below) turns water through an angle of 135° in a vertical plane. The flow cross section diameter is 400 mm at the elbow inlet, section (1), and 200 mm at the elbow outlet, section (2). The elbow flow passage volume is 0.2 m³ between sections (1) and (2). The water volume flowrate is 0.1 m³/s and the elbow inlet and outlet pressures are 140 kPa and 90 kPa. The elbow mass is 11 kg. Calculate the (a) horizontal (x direction) and (b) vertical (z direction) anchoring forces required to hold the elbow in place. D₂- Section (1)- D₁ = 400 mm 135° 200 mm Section (2) (a) Fx= i 20809.96 N (b) Fz= i -120265 N

2: A rectangular aluminum block is loaded uniformly in three directions. The loadings are as follows:a 50 kN total resulting compressive load in the x-direction, a 200 kPa uniformly distributed tensile load in they-direction, and a 0.03 MN total resulting tensile load in the z-direction. The block has the following dimensions:L = 1 m, b = 20 cm, h = 350 mm. Use E = 70 GPa and ν = 0.25.Determine the strain in the x and y axes respectively. For the strain in the y-direction to be equal to 0, how much uniformly distributed load inthe surface of y-direction should be added? (+ for tensile, - for compressive) Answers: 5 -1.122 x10-5 / 3 decimals 6 5.102 x10-6 / 3 decimals 7 -0.357 MPa / 3 decimals

A spherical balloon with a diameter of 9 m is filled with water vapour at 200˚C and 200 kPa. Determine the mass of water in the balloon. The R value for water is 0.4615 kJ/kg∙K.

Chapter 6 Solutions

FUNDAMENTALS OF ENGINEERING THERMODYNAM

Ch. 6.13 - Prob. 1E Ch. 6.13 - Prob. 2E Ch. 6.13 - Prob. 3E Ch. 6.13 - Prob. 4E Ch. 6.13 - Prob. 5E Ch. 6.13 - 6. Is entropy produced within a system undergoing...Ch. 6.13 - 7. When a mixture of olive oil and vinegar...Ch. 6.13 - Prob. 8E Ch. 6.13 - Prob. 9E Ch. 6.13 - 10. Is Eq. 6.51a restricted to adiabatic processes...

Knowledge Booster

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, mechanical-engineering and related others by exploring similar questions and additional content below.