CONNECT FOR THERMODYNAMICS: AN ENGINEERI
CONNECT FOR THERMODYNAMICS: AN ENGINEERI
9th Edition
ISBN: 9781260048636
Author: CENGEL
Publisher: MCG
bartleby

Concept explainers

bartleby

Videos

Textbook Question
Book Icon
Chapter 12.6, Problem 72P

Saturated water vapor at 300°C is expanded while its pressure is kept constant until its temperature is 700°C. Calculate the change in the specific enthalpy and entropy using (a) the departure charts and (b) the property tables.

(a)

Expert Solution
Check Mark
To determine

The change in specific enthalpy and entropy of saturated water per unit mass using departure charts.

Answer to Problem 72P

The change in specific enthalpy and entropy of saturated water per unit mass using departure charts is 973kJ/kg and 1.2954kJ/kgK respectively.

Explanation of Solution

At ideal gas state, the enthalpy is the function of temperature only.

Write the formula for difference in molar specific enthalpy of water vapor at ideal gas state.

(h2¯h1¯)ideal=h2¯ideal(T2)h1¯ideal(T1) (I)

Here, the molar enthalpy at ideal gas state corresponding to the temperature is h¯(T) and the subscripts 1 and 2 indicates initial and final states.

Write the formula for change in molar specific entropy.

(s2¯s1¯)ideal=s2¯s1¯RulnP2P1 (II)

Here, the molar specific entropy at reference sate is s°¯, the universal gas constant is Ru, the pressure is P, and the subscripts 1 and 2 indicates initial and final states.

Write formula for enthalpy departure factor (Zh) on molar basis.

Zh=(h¯idealh¯)T,PRuTcr (III)

Here, the molar enthalpy at ideal gas state is h¯ideal, the molar enthalpy and normal state is h¯, the universal gas constant is Ru, and the critical temperature is Tcr; The subscripts T,P indicates the correspondence of given temperature and pressure.

Rearrange the Equation (III) to obtain h¯.

h¯=h¯idealZhRuTcr (IV)

Refer Equation (IV) express as two states of enthalpy difference (final – initial).

h¯2h¯1=(h¯2h¯1)ideal(Zh2Zh1)RuTcr (V)

Write formula for entropy departure factor (Zs) on molar basis.

Zs=(s¯ideals¯)T,PRu (VI)

Here, the molar entropy at ideal gas state is s¯ideal, the molar entropy and normal state is s¯, the universal gas constant is Ru, and the critical temperature is Tcr; The subscripts T,P indicates the correspondence of given temperature and pressure.

Rearrange the Equation (VI) to obtain s¯.

s¯=s¯idealZsRu (VII)

Refer Equation (VII) express as two states of entropy difference (final – initial).

s¯2s¯1=(s¯2s¯1)ideal(Zs2Zs1)Ru (VIII)

Write the formula for enthalpy (h) and entropy (s) changes per unit mass.

h2h1=h2¯h1¯M (IX)

s2s1=s2¯s1¯M (X)

Here, the molar enthalpy is h¯, the molar entropy s¯, and the molar mass of water is M.

Refer Table A-1, “Molar mass, gas constant, and critical-point properties”.

The critical temperature and pressure of water vapor gas is as follows.

Tcr=647.1KPcr=22.06MPa

Refer Table A-1, “Molar mass, gas constant, and critical-point properties”.

The molar mass (M) of water is 18.015kg/kmol.

The pressure is kept constant until its temperature reaches to 700°C.

P1=P2=Psat @ 300°C

Refer Table A-4, “Saturated water-Temperature table”.

The saturation pressure corresponding to the temperature of 700°C is 8587.9kPa8588kPa(8.588MPa).

The reduced pressure (PR1) and temperature (TR1) at initial state is expressed as follows.

TR1=T1Tcr=(300+273)K647.1K=0.885

PR1=P1Pcr=8.588MPa22.06MPa=0.389

The reduced pressure (PR2) and temperature (TR2) at final state is expressed as follows.

TR2=T2Tcr=(700+273)K647.1K=1.504

PR2=P2Pcr=8.588MPa22.06MPa=0.389

At initial:

Refer Figure A-29, “Generalized enthalpy departure chart”.

The enthalpy departure factor (Zh1) corresponding the reduced pressure (PR1) and reduced temperature (TR1) is 0.609.

Refer Figure A-30, “Generalized entropy departure chart”.

The entropy departure factor (Zs1) corresponding the reduced pressure (PR1) and reduced temperature (TR1) is 0.481.

At final:

Refer Figure A-29, “Generalized enthalpy departure chart”.

The enthalpy departure factor (Zh2) corresponding the reduced pressure (PR2) and reduced temperature (TR2) is 0.204.

Refer Figure A-30, “Generalized entropy departure chart”.

The entropy departure factor (Zs2) corresponding the reduced pressure (PR2) and reduced temperature (TR2) is 0.105.

Refer Table A-19, “Ideal-gas properties of water vapor, H2O”.

Obtain the initial properties corresponding to the temperature of 573K.

h1¯=19426kJ/kmols1¯=211.263kJ/kmolK

Obtain the final properties corresponding to the temperature of 973K.

h2¯=34775kJ/kmols2¯=231.473kJ/kmolK

The universal gas constant (Ru) is 8.314kJ/kmolK.

Conclusion:

Substitute 34775kJ/kmol for h2¯ideal(T2) and 19426kJ/kmol for h1¯ideal(T1) in

Equation (I).

(h2¯h1¯)ideal=34775kJ/kmol19426kJ/kmol=15349kJ/kmol

Substitute 231.473kJ/kmolK for s2¯, 211.263kJ/kmolK for s1¯, 8.314kJ/kmolK for Ru, and 8.588MPa for P2, P1 in Equation (II).

(s2¯s1¯)ideal=[231.473kJ/kmolK211.263kJ/kmolK(8.314kJ/kmolK)ln8.588MPa8.588MPa]=20.21kJ/kmolK0=20.21kJ/kmolK

Substitute 15349kJ/kmol for (h¯2h¯1)ideal, 0.204 for Zh2, 0.609 for Zh1, 8.314kJ/kmolK for Ru, and 647.1K for Tcr in Equation (V).

h¯2h¯1={15349kJ/kmol[(0.2040.609)(8.314kJ/kmolK)(647.1K)]}=15349kJ/kmol+2178.8957kJ/kmol=17527.8957kJ/kmol17528kJ/kmol

Substitute 20.21kJ/kmolK for (s¯2s¯1)ideal, 0.105 for Zs2, 0.481 for Zs1, and 8.314kJ/kmolK for Ru, in Equation (VIII).

s¯2s¯1={20.21kJ/kmolK[(0.1050.481)(8.314kJ/kmolK)]}=20.21kJ/kmolK+3.1260kJ/kmolK=23.336kJ/kmolK

Substitute 17528kJ/kmol for h2¯h1¯ and 18.015kg/kmol for M in Equation (IX).

h2h1=17528kJ/kmol18.015kg/kmol=972.9669kJ/kg=973kJ/kg

Substitute 23.336kJ/kmolK for s2¯s1¯ and 18.015kg/kmol for M in Equation (X).

s2s1=23.336kJ/kmolK18.015kg/kmol=1.2954kJ/kgK

Thus, the change in specific enthalpy and entropy of saturated water per unit mass using departure charts is 973kJ/kg and 1.2954kJ/kgK respectively.

(a)

Expert Solution
Check Mark
To determine

The change in specific enthalpy and entropy of water vapor per unit mass using property tables.

Answer to Problem 72P

The change in specific enthalpy and entropy of water vapor per unit mass using property tables is 1129kJ/kg and 1.5405kJ/kgK respectively.

Explanation of Solution

At state 1:

The steam is at state of saturated vapor at the temperature of 300°C. Hence, the enthalpy (h1) and entropy (s1) at state 1 is expressed as follows.

h1=hg@300°Cs1=sg@300°C

Refer Table A-4, “Saturated water-Temperature table”.

The enthalpy (h1) and entropy (s1) at state 1 corresponding to the temperature of 300°C is 2749.6kJ/kg and 5.7059kJ/kgK respectively.

At state 2:

The water vapor is expanded to the temperature of 700°C by keeping the pressure as constant. This makes the saturated vapor into to superheated vapor.

The pressure is kept constant until its temperature reaches to 700°C.

P1=P2=Psat @ 300°C

Refer Table A-4, “Saturated water-Temperature table”.

The saturation pressure corresponding to the temperature of 700°C is 8587.9kPa8588kPa(8.588MPa).

Refer Table A-6, “Superheated water”.

Obtain the enthalpy (h2) and entropy (s2) at state 2 corresponding to the pressure of 8.588MPa and the temperature of 700°C by interpolating the tables.

h2=3878.6kJ/kgs2=7.2465kJ/kgK

Conclusion:

The enthalpy changes are expressed as follows.

h2h1=3878.6kJ/kg2749.6kJ/kg=1129kJ/kg

The entropy changes are expressed as follows.

s2s1=7.2464kJ/kgK5.7059kJ/kgK=1.5405kJ/kgK

Thus, the change in specific enthalpy and entropy of water vapor per unit mass using property tables is 1129kJ/kg and 1.5405kJ/kgK respectively.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!
Students have asked these similar questions
Determine the specific volume, entropy, and enthalpy of compressed liquid water at 90oC and 150 bar using the saturated liquid approximation. .   Answers: 0.001m3 /kg, 377 kJ/kg, 1.193 kJ/kg - STEPS ON HOW TO REACH THESE
Steam at 300 kPa and 200C undergoes an isentropic process where it expands until it becomes 30 kPa. Solve for the change in enthalpy.
A frictionless piston-cylinder contains 42 kilograms of Acetylene having a pressure of 22 bar at 320 degrees Celsius. Heating occurs at constant pressure causing the piston to move until the volume is tripled. Compute  for the (a) heat, (b) change in internal energy, (c) change in enthalpy (d) change in entropy, and (e) the non-flow work. (f) If ΔPE = 0.2 kJ and ΔKE = 1.35 kJ, what is the steady-flow work?

Chapter 12 Solutions

CONNECT FOR THERMODYNAMICS: AN ENGINEERI

Ch. 12.6 - Consider an ideal gas at 400 K and 100 kPa. As a...Ch. 12.6 - Using the equation of state P(v a) = RT, verify...Ch. 12.6 - Prove for an ideal gas that (a) the P = constant...Ch. 12.6 - Verify the validity of the last Maxwell relation...Ch. 12.6 - Verify the validity of the last Maxwell relation...Ch. 12.6 - Show how you would evaluate T, v, u, a, and g from...Ch. 12.6 - Prob. 18PCh. 12.6 - Prob. 19PCh. 12.6 - Prob. 20PCh. 12.6 - Prove that (PT)=kk1(PT)v.Ch. 12.6 - Prob. 22PCh. 12.6 - Prob. 23PCh. 12.6 - Using the Clapeyron equation, estimate the...Ch. 12.6 - Prob. 26PCh. 12.6 - Determine the hfg of refrigerant-134a at 10F on...Ch. 12.6 - Prob. 28PCh. 12.6 - Prob. 29PCh. 12.6 - Two grams of a saturated liquid are converted to a...Ch. 12.6 - Prob. 31PCh. 12.6 - Prob. 32PCh. 12.6 - Prob. 33PCh. 12.6 - Prob. 34PCh. 12.6 - Prob. 35PCh. 12.6 - Prob. 36PCh. 12.6 - Determine the change in the internal energy of...Ch. 12.6 - Prob. 38PCh. 12.6 - Determine the change in the entropy of helium, in...Ch. 12.6 - Prob. 40PCh. 12.6 - Estimate the specific heat difference cp cv for...Ch. 12.6 - Derive expressions for (a) u, (b) h, and (c) s for...Ch. 12.6 - Derive an expression for the specific heat...Ch. 12.6 - Derive an expression for the specific heat...Ch. 12.6 - Derive an expression for the isothermal...Ch. 12.6 - Prob. 46PCh. 12.6 - Show that cpcv=T(PT)V(VT)P.Ch. 12.6 - Show that the enthalpy of an ideal gas is a...Ch. 12.6 - Prob. 49PCh. 12.6 - Show that = ( P/ T)v.Ch. 12.6 - Prob. 51PCh. 12.6 - Prob. 52PCh. 12.6 - Prob. 53PCh. 12.6 - Prob. 54PCh. 12.6 - Prob. 55PCh. 12.6 - Does the Joule-Thomson coefficient of a substance...Ch. 12.6 - The pressure of a fluid always decreases during an...Ch. 12.6 - Will the temperature of helium change if it is...Ch. 12.6 - Estimate the Joule-Thomson coefficient of...Ch. 12.6 - Estimate the Joule-Thomson coefficient of...Ch. 12.6 - Prob. 61PCh. 12.6 - Steam is throttled slightly from 1 MPa and 300C....Ch. 12.6 - What is the most general equation of state for...Ch. 12.6 - Prob. 64PCh. 12.6 - Consider a gas whose equation of state is P(v a)...Ch. 12.6 - Prob. 66PCh. 12.6 - What is the enthalpy departure?Ch. 12.6 - On the generalized enthalpy departure chart, the...Ch. 12.6 - Why is the generalized enthalpy departure chart...Ch. 12.6 - What is the error involved in the (a) enthalpy and...Ch. 12.6 - Prob. 71PCh. 12.6 - Saturated water vapor at 300C is expanded while...Ch. 12.6 - Determine the enthalpy change and the entropy...Ch. 12.6 - Prob. 74PCh. 12.6 - Prob. 75PCh. 12.6 - Prob. 77PCh. 12.6 - Propane is compressed isothermally by a...Ch. 12.6 - Prob. 81PCh. 12.6 - Prob. 82RPCh. 12.6 - Starting with the relation dh = T ds + vdP, show...Ch. 12.6 - Using the cyclic relation and the first Maxwell...Ch. 12.6 - For ideal gases, the development of the...Ch. 12.6 - Show that cv=T(vT)s(PT)vandcp=T(PT)s(vT)PCh. 12.6 - Temperature and pressure may be defined as...Ch. 12.6 - For a homogeneous (single-phase) simple pure...Ch. 12.6 - For a homogeneous (single-phase) simple pure...Ch. 12.6 - Prob. 90RPCh. 12.6 - Prob. 91RPCh. 12.6 - Estimate the cpof nitrogen at 300 kPa and 400 K,...Ch. 12.6 - Prob. 93RPCh. 12.6 - Prob. 94RPCh. 12.6 - Prob. 95RPCh. 12.6 - Methane is to be adiabatically and reversibly...Ch. 12.6 - Prob. 97RPCh. 12.6 - Prob. 98RPCh. 12.6 - Prob. 99RPCh. 12.6 - An adiabatic 0.2-m3 storage tank that is initially...Ch. 12.6 - Prob. 102FEPCh. 12.6 - Consider the liquidvapor saturation curve of a...Ch. 12.6 - For a gas whose equation of state is P(v b) = RT,...Ch. 12.6 - Prob. 105FEPCh. 12.6 - Prob. 106FEP
Knowledge Booster
Background pattern image
Mechanical Engineering
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.
Similar questions
SEE MORE QUESTIONS
Recommended textbooks for you
Text book image
Elements Of Electromagnetics
Mechanical Engineering
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Oxford University Press
Text book image
Mechanics of Materials (10th Edition)
Mechanical Engineering
ISBN:9780134319650
Author:Russell C. Hibbeler
Publisher:PEARSON
Text book image
Thermodynamics: An Engineering Approach
Mechanical Engineering
ISBN:9781259822674
Author:Yunus A. Cengel Dr., Michael A. Boles
Publisher:McGraw-Hill Education
Text book image
Control Systems Engineering
Mechanical Engineering
ISBN:9781118170519
Author:Norman S. Nise
Publisher:WILEY
Text book image
Mechanics of Materials (MindTap Course List)
Mechanical Engineering
ISBN:9781337093347
Author:Barry J. Goodno, James M. Gere
Publisher:Cengage Learning
Text book image
Engineering Mechanics: Statics
Mechanical Engineering
ISBN:9781118807330
Author:James L. Meriam, L. G. Kraige, J. N. Bolton
Publisher:WILEY
What is entropy? - Jeff Phillips; Author: TED-Ed;https://www.youtube.com/watch?v=YM-uykVfq_E;License: Standard youtube license