THERMODYNAMICS-SI ED. EBOOK >I<
THERMODYNAMICS-SI ED. EBOOK >I<
9th Edition
ISBN: 9781307573022
Author: CENGEL
Publisher: MCG/CREATE
bartleby

Concept explainers

bartleby

Videos

Textbook Question
Book Icon
Chapter 8.8, Problem 114RP

A 4-L pressure cooker has an operating pressure of 175 kPa. Initially, one-half of the volume is filled with liquid water and the other half by water vapor. The cooker is now placed on top of a 750-W electrical heating unit that is kept on for 20 min. Assuming the surroundings to be at 25°C and 100 kPa, determine (a) the amount of water that remained in the cooker and (b) the exergy destruction associated with the entire process.

Chapter 8.8, Problem 114RP, A 4-L pressure cooker has an operating pressure of 175 kPa. Initially, one-half of the volume is

FIGURE P8–114

(a)

Expert Solution
Check Mark
To determine

The final mass of water that remained in the cooker.

Answer to Problem 114RP

The final mass of water that remained in the cooker is 1.507kg.

Explanation of Solution

Express the mass balance for a pressure cooker which acts as a system.

minmout=Δmsystemme=m1m2 (I)

Here, initial mass is min(m1), difference in the mass of a states is me, change in mass of a system is Δmsystem, and final mass is mout(m2).

Write an energy balance for a system.

EinEout=ΔEsystemWe,in+mehe=m2u2m1u1 (II)

Here, internal energy at state 1 and 2 is u1andu2, enthalpy at state e is he, energy transfer at inlet and outlet condition is EinandEout respectively, and change in energy transfer of a system is ΔEsystem, and amount of electrical energy supplied during the process is We,in.

Calculate the initial mass in the tank (m1).

m1=mf+mg=Vfvf+Vgvg (III)

Here, saturated liquid specific volume is vf, saturated vapor specific volume is vg, volume at saturated liquid and vapor is VfandVg respectively.

Calculate the initial internal energy (U1) in the tank.

U1=m1u1=mfuf+mgug (IV)

Here, specific internal energy of saturated fluid is uf and the specific internal energy of saturated vapor is ug.

Calculate the initial entropy (S1) in the tank.

S1=m1s1=mfsf+mgsg (V)

Here, specific entropy of saturated fluid is sf and the specific entropy of saturated vapor is sg.

Write the internal energy at state 2(u2).

u2=uf+x2(uguf) (VI)

Here, dryness fraction at state 2 is x2.

Write the specific volume at state 2(v2).

v2=vf+x2(vgvf) (VII)

Write the formula to calculate the mass of the water remained in tank (m2).

m2=Vv2 (VIII)

Here, volume of the cooker is V and the final specific volume of water is v2.

Conclusion:

From the Table A-5 of “Saturated water: Pressure”, obtain the saturated liquid specific volume (vf), saturated vapor specific volume (vg), saturated liquid enthalpy (uf), saturated vapor enthalpy (ug), saturated liquid entropy (sf), and saturated vapor entropy (sg) at initial pressure (P1=175kPa) as

vf=0.001057m3/kgvg=1.0037m3/kguf=486.82kJ/kgug=2524.5kJ/kg

sf=1.4850kJ/kgKsg=7.1716kJ/kgK

From the Table A-5 of “Saturated water: Pressure”, obtain the enthalpy (he) and entropy (se) at the microscopic energy of flowing at pressure (Pe=175kPa) as,

he=hghe=2700.2kJ/kgse=sgse=7.1716kJ/kgK

Since one half of the volume is filled with liquid water and other half by water vapor, calculate the volume of tank (Vf).

Vf=Vg=2L=2L×0.001m3L=0.002m3

Substitute 0.002m3 for Vf, 0.002m3 for Vg, 0.001057m3/kg for vf, and 1.0037m3/kg for vg in Equation (III).

m1=0.002m30.001057m3/kg+0.002m31.0037m3/kg=1.893+0.002=1.8945kg

Substitute 1.893 kg for mf, 486.82kJ/kg for uf, 0.002 kg for mg, and 2524.5kJ/kg for ug in Equation (IV).

U1=(1.893kg)(486.82kJ/kg)+(0.002kg)(2524.5kJ/kg)=926.6kJ

Substitute 1.893 kg for mf, 1.4850kJ/kgK for sf, 0.002 kg for mg, and 7.1716kJ/kgK for sg in Equation (V).

S1=(1.893kg)(1.4850kJ/kgK)+(0.002kg)(7.1716kJ/kgK)=2.8239kJ/K

Substitute 486.82kJ/kg for uf and 2524.5kJ/kg for ug in Equation (VI).

u2=486.82kJ/kg+x2(2524.5kJ/kg486.82kJ/kg)

u2=486.82+x2(2037.68)

Substitute 0.001057m3/kg for vf and 1.0037m3/kg for vg Equation (VII).

v2=0.001057m3/kg+x2(1.0037m3/kg0.001057m3/kg)

v2=0.001057+x2(1.002643) (IX)

Re-write the Equation (II) using the Equation (I),

We,in=(m1m2)he+m2u2m1u1 (X)

Substitute 900kJ for We,in, 1.8945kg for m1, 2700.2kJ/kg for he, [486.82+x2(2037.68)] for u2, 0.004v2 for m2, and 926.6kJ for m1u1 in Equation (X).

900kJ={(1.8945kg0.004v2)2700.2kJ/kg+(0.004v2)([486.82+x2(2037.68)])926.6kJ}

Substitute [0.001057+x2(1.002643)] for v2.

900kJ={(1.8945kg0.004[0.001057+x2(1.002643)])2700.2kJ/kg+0.0040.001057+x2(1.002643)[486.82+x2(2037.68)]926.6kJ}x2=0.001918

Substitute 0.001918 for x2 in Equation (IX).

v2=0.001057+0.001918(1.002643)=0.002654m3/kg

Substitute 0.004m3 for V and 0.002654m3/kg for v2

m2=0.004m30.002654m3/kg=1.507kg

Thus, the final mass of water that remained in the cooker is 1.507kg.

(b)

Expert Solution
Check Mark
To determine

The amount of exergy destructed during the heating process.

Answer to Problem 114RP

The amount of exergy destructed during the heating process is 669.8kJ.

Explanation of Solution

For a closed system, write the simplification rate form of the entropy balance on an extended system which includes cooker and its immediate surroundings.

SinSout+Sgen=ΔSsystemmese+Sgen=m2s2m1s1Sgen=m2s2m1s1+mese (XI)

Here, entropy generation is Sgen, change of entropy is ΔSsystem, entropy at inlet condition is Sin, entropy at outlet condition is Sout,

Calculate the exergy destroyed during the process (Xdestroyed).

Xdestroyed=T0Sgen (XII)

Here, dead state temperature is T0.

Substitute Equation (XI) in Equation (XII).

Xdestroyed=T0(m2s2m1s1+mese) (XIII)

Calculate the entropy at state 2(s2).

s2=sf+x2(sgsf) (XIV)

Conclusion:

Substitute 0.001918 for x2, 1.4850kJ/kgK for sf and 7.1716kJ/kgK for sg in Equation (XIV).

s2=1.4850kJ/kgK+0.001918(7.1716kJ/kgK1.4850kJ/kgK)=1.5642kJ/kgK

Substitute 1.8945 kg for m1 and 1.507 kg for m2 in Equation (I).

me=1.8945kg1.507kg=0.3875kg

Substitute 298 K for T0, 1.507 kg for m2, 1.5642kJ/kgK for s2,2.8239kJ/K for m1s1, 0.3875 kg for me, and 7.1716kJ/kgK for se in Equation (XIII).

Xdestroyed=298K(1.507kg(1.5642kJ/kgK)(2.8239kJ/K)+0.3785kg(7.1716kJ/kgK))=298(2.35722.8239+2.7144)=669.8kJ

Thus, the amount of exergy destructed during the heating process is 669.8kJ.

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
Refrigerant-22 absorbs heat from a cooled space at 50°F as it flows through an evaporator of a refrigeration system. R-22 enters the evaporator at 10°F at a rate of 0.08 lbm/s with a quality of 0.3 and leaves as a saturated vapor at the same pressure. Determine the rate of exergy destruction in the evaporato.
A well-insulated rigid tank contains 6 lbm of a saturated liquid–vapor mixture of water at 35 psia. Initially, three-quarters of the mass is in the liquid phase. An electric resistance heater placed in the tank is turned on and kept on until all the liquid in the tank is vaporized. Assuming the surroundings to be at 75°F and 14.7 psia, determine the exergy destruction.
2. A piston-cylinder device contains 8 kg of refrigerant- 134a at 0.7 MPa and 60°C. The refrigerant is now cooled at constant pressure until it exists as a liquid at 20°C. If the surroundings are at 100 kPa and 20°C, determine (a) the exergy of the refrigerant at the initial and the final states and (b) the exergy destroyed during this process.

Chapter 8 Solutions

THERMODYNAMICS-SI ED. EBOOK >I<

Ch. 8.8 - Prob. 11PCh. 8.8 - Does a power plant that has a higher thermal...Ch. 8.8 - Prob. 13PCh. 8.8 - Saturated steam is generated in a boiler by...Ch. 8.8 - One method of meeting the extra electric power...Ch. 8.8 - A heat engine that receives heat from a furnace at...Ch. 8.8 - Consider a thermal energy reservoir at 1500 K that...Ch. 8.8 - A heat engine receives heat from a source at 1100...Ch. 8.8 - A heat engine that rejects waste heat to a sink at...Ch. 8.8 - A geothermal power plant uses geothermal liquid...Ch. 8.8 - A house that is losing heat at a rate of 35,000...Ch. 8.8 - A freezer is maintained at 20F by removing heat...Ch. 8.8 - Prob. 24PCh. 8.8 - Prob. 25PCh. 8.8 - Prob. 26PCh. 8.8 - Can a system have a higher second-law efficiency...Ch. 8.8 - A mass of 8 kg of helium undergoes a process from...Ch. 8.8 - Which is a more valuable resource for work...Ch. 8.8 - Which has the capability to produce the most work...Ch. 8.8 - The radiator of a steam heating system has a...Ch. 8.8 - A well-insulated rigid tank contains 6 lbm of a...Ch. 8.8 - A pistoncylinder device contains 8 kg of...Ch. 8.8 - Prob. 35PCh. 8.8 - Prob. 36PCh. 8.8 - Prob. 37PCh. 8.8 - A pistoncylinder device initially contains 2 L of...Ch. 8.8 - A 0.8-m3 insulated rigid tank contains 1.54 kg of...Ch. 8.8 - An insulated pistoncylinder device initially...Ch. 8.8 - Prob. 41PCh. 8.8 - An insulated rigid tank is divided into two equal...Ch. 8.8 - A 50-kg iron block and a 20-kg copper block, both...Ch. 8.8 - Prob. 45PCh. 8.8 - Prob. 46PCh. 8.8 - Prob. 47PCh. 8.8 - A pistoncylinder device initially contains 1.4 kg...Ch. 8.8 - Prob. 49PCh. 8.8 - Prob. 50PCh. 8.8 - Prob. 51PCh. 8.8 - Air enters a nozzle steadily at 200 kPa and 65C...Ch. 8.8 - Prob. 54PCh. 8.8 - Prob. 55PCh. 8.8 - Argon gas enters an adiabatic compressor at 120...Ch. 8.8 - Prob. 57PCh. 8.8 - Prob. 58PCh. 8.8 - The adiabatic compressor of a refrigeration system...Ch. 8.8 - Refrigerant-134a at 140 kPa and 10C is compressed...Ch. 8.8 - Air enters a compressor at ambient conditions of...Ch. 8.8 - Combustion gases enter a gas turbine at 900C, 800...Ch. 8.8 - Steam enters a turbine at 9 MPa, 600C, and 60 m/s...Ch. 8.8 - Refrigerant-134a is condensed in a refrigeration...Ch. 8.8 - Prob. 66PCh. 8.8 - Refrigerant-22 absorbs heat from a cooled space at...Ch. 8.8 - Prob. 68PCh. 8.8 - Prob. 69PCh. 8.8 - Air enters a compressor at ambient conditions of...Ch. 8.8 - Hot combustion gases enter the nozzle of a...Ch. 8.8 - Prob. 72PCh. 8.8 - A 0.6-m3 rigid tank is filled with saturated...Ch. 8.8 - Prob. 74PCh. 8.8 - Prob. 75PCh. 8.8 - An insulated vertical pistoncylinder device...Ch. 8.8 - Liquid water at 200 kPa and 15C is heated in a...Ch. 8.8 - Prob. 78PCh. 8.8 - Prob. 79PCh. 8.8 - A well-insulated shell-and-tube heat exchanger is...Ch. 8.8 - Steam is to be condensed on the shell side of a...Ch. 8.8 - Prob. 82PCh. 8.8 - Prob. 83PCh. 8.8 - Prob. 84PCh. 8.8 - Prob. 85RPCh. 8.8 - Prob. 86RPCh. 8.8 - An aluminum pan has a flat bottom whose diameter...Ch. 8.8 - Prob. 88RPCh. 8.8 - Prob. 89RPCh. 8.8 - A well-insulated, thin-walled, counterflow heat...Ch. 8.8 - Prob. 92RPCh. 8.8 - Prob. 93RPCh. 8.8 - Prob. 94RPCh. 8.8 - Prob. 95RPCh. 8.8 - Nitrogen gas enters a diffuser at 100 kPa and 110C...Ch. 8.8 - Prob. 97RPCh. 8.8 - Steam enters an adiabatic nozzle at 3.5 MPa and...Ch. 8.8 - Prob. 99RPCh. 8.8 - A pistoncylinder device initially contains 8 ft3...Ch. 8.8 - An adiabatic turbine operates with air entering at...Ch. 8.8 - Steam at 7 MPa and 400C enters a two-stage...Ch. 8.8 - Prob. 103RPCh. 8.8 - Steam enters a two-stage adiabatic turbine at 8...Ch. 8.8 - Prob. 105RPCh. 8.8 - Prob. 106RPCh. 8.8 - Prob. 107RPCh. 8.8 - Prob. 108RPCh. 8.8 - Prob. 109RPCh. 8.8 - Prob. 111RPCh. 8.8 - A passive solar house that was losing heat to the...Ch. 8.8 - Prob. 113RPCh. 8.8 - A 4-L pressure cooker has an operating pressure of...Ch. 8.8 - Repeat Prob. 8114 if heat were supplied to the...Ch. 8.8 - Prob. 116RPCh. 8.8 - A rigid 50-L nitrogen cylinder is equipped with a...Ch. 8.8 - Prob. 118RPCh. 8.8 - Prob. 119RPCh. 8.8 - Prob. 120RPCh. 8.8 - Reconsider Prob. 8-120. The air stored in the tank...Ch. 8.8 - Prob. 122RPCh. 8.8 - Prob. 123RPCh. 8.8 - Prob. 124RPCh. 8.8 - Prob. 125RPCh. 8.8 - Prob. 126RPCh. 8.8 - Prob. 127RPCh. 8.8 - Water enters a pump at 100 kPa and 30C at a rate...Ch. 8.8 - Prob. 129RPCh. 8.8 - Prob. 130RPCh. 8.8 - Obtain a relation for the second-law efficiency of...Ch. 8.8 - Writing the first- and second-law relations and...Ch. 8.8 - Prob. 133RPCh. 8.8 - Keeping the limitations imposed by the second law...Ch. 8.8 - Prob. 135FEPCh. 8.8 - Prob. 136FEPCh. 8.8 - Prob. 137FEPCh. 8.8 - Prob. 138FEPCh. 8.8 - A furnace can supply heat steadily at 1300 K at a...Ch. 8.8 - A heat engine receives heat from a source at 1500...Ch. 8.8 - Air is throttled from 50C and 800 kPa to a...Ch. 8.8 - Prob. 142FEPCh. 8.8 - A 12-kg solid whose specific heat is 2.8 kJ/kgC is...
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