| Reversible Adiabatic Expansion of Nitrogen.Nitrogen expands reversibly in an insulated cylinder fitted with a piston. The N2 is initially at 500K and 5bar pressure and expands to a final pressure of 1 bar.Determine the final temperature T of the N2 (in K) as well as the work done in the process W (J/mol),assuming N2 to be in the ideal gas state. Heat capacity, C, is equal to a constant at 3.560R.

Given: Nitrogen which is assumed to be an ideal gas expands reversibly and adiabatically, P1 = 5 bar…

Answered: | Reversible Adiabatic Expansion of…

Introduction to Chemical Engineering Thermodynamics

8th Edition

ISBN:9781259696527

Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart

Publisher:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart

Chapter1: Introduction

Section: Chapter Questions

Problem 1.1P

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An adiabatic steam turbine in an electric power plant is designed to accept steam at 5000 kPa and 600°C and discharge the steam at 101.3 kPa. a) What is the exit temperature of the steam and the work produced (per kg of steam) if the turbine operates adiabatically and reversibly? b) If the turbine operated adiabatically but irreversibly, with an isentropie efficieney of 80 %, what would be the exit temperature and the work produced (per kg of steam)? c) For part b, what is the entropy generation Sa?
A piston/cylinder contains 0.5 kg nitrogen gas at 750 K and 1500 kPa. Now it is expanded in a polytropic process to P= 750 kPa and T= 668 K. Find the total heat transfer in the process.
A diatomic ideal gas undergoes the exact same four step process as in problem 1A, starting at PointA (400 kPa, 600K, 1 L) A => B Isobaric expansion that triples the volume B => C Isochoric cooling to one-half the pressure C=> D Isobaric contraction to the original volume. D => A Isochoric heating to original pressure Determine the Pressure, Temperature and Volume at the end of each process. Determine the Change in the Internal Energy, Heat Flow and Work Done by the System during each process and for the entire cycle. Sketch a well labeled PV diagram for this cycle. Determine the Thermal Efficiency of this cycle (Work for Cycle/Heat Flow Into the System).
Consider an ideal gas which is being throttled to a pressure of 1 bar at a rate of 100 mol/s The initial pressure of the system is 25 bar. Given the temperature of the surrounding as 300 K. Calculate the following quantities (a) Rate of entropy generation Lost work
11-14. The mixture in Problem 11-1 is contained in a rigid vessel and is heated to a temperature of 120°C by transferring heat from a thermal-energy reservoir having a temperature of 300°C. The volume of the vessel is 0.4 m³, and the environment is at 25°C and 100 kPa. Determine the amount of heat transfer required.
One mole of an ideal gas (=3.5R) at 127C and 5 bar throttles through a valve where its pressure decreases to 1 bar. Determine: P3.1 The exit temperature, if the valve is fully insulated. P3.2, if the valve is fully insulated. P3.3 The exit temperature, if there is 1 kJ heat loss in the throttling Process P3.4, if there is 1 kJ heat loss in the throttling Process..

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