Physics for Scientists and Engineers, Technology Update (No access codes included)
Physics for Scientists and Engineers, Technology Update (No access codes included)
9th Edition
ISBN: 9781305116399
Author: Raymond A. Serway, John W. Jewett
Publisher: Cengage Learning
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Chapter 22, Problem 22.82CP

The compression ratio of an Otto cycle as shown in Figure 21.12 is VA/VB = 8.00. At the beginning A of the compression process, 500 cm3 of gas is at 100 kPa and 20.0°C. At the beginning of the adiabatic expansion, the temperature is TC = 750°C. Model the working fluid as an ideal gas with γ = 1.40. (a) Fill in this table to follow the states of the gas:

Chapter 22, Problem 22.82CP, The compression ratio of an Otto cycle as shown in Figure 21.12 is VA/VB = 8.00. At the beginning A , example  1

(b) Fill in this table to follow the processes:

Chapter 22, Problem 22.82CP, The compression ratio of an Otto cycle as shown in Figure 21.12 is VA/VB = 8.00. At the beginning A , example  2

(c) Identify the energy input |Qh|, (d) the energy exhaust |Qc|, and (e) the net output work Weng. (f) Calculate the efficiency. (g) Find the number of crankshaft revolutions per minute required for a one-cylinder engine to have an output power of 1.00 kW = 1.34 hp. Note: The thermodynamic cycle involves four piston strokes.

(a)

Expert Solution
Check Mark
To determine

The states of the gas during the Otto cycle.

Answer to Problem 22.82CP

The complete table is shown below.

StateT(K)P(kPa)V(cm3)
A293100500
B6731.84×10362.5
C10232.79×10362.5
D445152500

Explanation of Solution

The compression ratio of an Otto cycle is VAVB=8.00, at the beginning of A, the initial volume of the gas is 500cm3 and the initial temperature and pressure of gas is 20.0°C and 100kPa. At the beginning of the adiabatic expansion, the temperature is TC=750°C. The adiabatic index is 1.4.

In Otto cycle, the process AB is adiabatic compression, BC is isovolumetric heat addition, CD is adiabatic expansion and DA is isovolumetric heat removal.

Write the expression to calculate the quantity of the gas.

    n=PAVARTA

Here, PA is the pressure of the gas at point A, VA is the volume of the gas at point A, TA is the temperature at point A, R is the universal gas constant and n is the number of moles.

Substitute 100kPa for PA, 500cm3 for VA, 20.0°C for TA and 8.314J/molK for R in above equation to find n.

  n=(100kPa×1000Pa1kPa)(500cm3×106m31cm3)(8.314J/molK)(20.0°C+273)K=0.0205mol

In process AB,

Write the expression to calculate the pressure at point B.

    PB=PA(VAVB)γ

Here, PB is the pressure of the gas at point B, VB is the volume of the gas at point B and γ is the specific heat ratio.

Substitute 8  for VAVB, 1.40 for γ and 100kPa for PA in above equation.

    PB=(100kPa×1000Pa1kPa)(8)1.40=1.84×106Pa=1.84×106Pa×103kPa1Pa=1.84×103kPa

Write the expression for the compression ratio

    VAVB=8.00

Substitute 500cm3 for VA in above equation.

    VAVB=8.00VB=62.5cm3

Write the expression to calculate the temperature at point B.

    TB=PBVBnR

Substitute 1.84×106Pa for PB, 62.5cm3 for VB, 0.0205mol for n and 8.314J/molK for R in above equation.

    TB=(1.84×106Pa)(62.5cm3×106m31cm3)0.0205mol×(8.314J/molK)=673K

At state C:

    VC=VB

Here, VC is the volume of the gas at point C.

Write the expression to calculate the pressure at point C.

    PC=nRTCVC

Here, PC is the pressure of the gas at point C and TC is the temperature at point C.

Substitute 62.5cm3 for VC, 0.0205mol for n, 8.314J/molK for R and 750°C for TC in above equation.

    PC=(0.0205mol)(8.314J/molK)×(750°C+273)K(62.5cm3×106m31cm3)=2.79×106Pa=2.79×106Pa×103kPa1Pa=2.79×103kPa

State D:

    VD=VA and VC=VB

Here, VD is the volume of the gas at point D.

Therefore, the compression ratio

    (VCVD)=VBVA=18

Write the expression to calculate the pressure at point D.

    PD=PC(VCVD)γ

Here, PD is the pressure of the gas at point D and TD is the temperature at point D.

Substitute 2.79×106Pa for PC and 18 for (VCVD) in above equation.

    PD=(2.79×106Pa)(18)1.4=1.52×105Pa=1.52×105Pa×103kPa1Pa=152kPa

Write the expression to calculate the temperature at point D.

    TD=PDVDnR

Substitute 1.52×105Pa for PD, 500cm3 for VD, 0.0205mol for n and 8.314J/molK for R in above equation.

    TD=(1.52×105Pa)(500cm3×106m31cm3)(0.0205mol)(8.314J/molK)=445K

From the above explanation, the complete table is given below.

StateT(K)P(kPa)V(cm3)
A293100500
B6731.84×10362.5
C10232.79×10362.5
D445152500

Conclusion:

Therefore, the complete table is given below.

StateT(K)P(kPa)V(cm3)
A293100500
B6731.84×10362.5
C10232.79×10362.5
D445152500

(b)

Expert Solution
Check Mark
To determine

The heat transferred, work done and the change in internal energy during the different process in the Otto cycle.

Answer to Problem 22.82CP

The complete table is shown below.

ProcessQWengΔEint
AB0-162162
BC1490149
CD0246-246
DA-650-65
ABCD84.384.30

Explanation of Solution

The process AB is adiabatic and hence there is no transfer of heat during this process. Thus, Q=0 in this process.

Let Q be the heat transferred, ΔE is the change in internal energy and Wout is the work done.

Write the expression for change in internal energy in A to B process.

    ΔEintAB=52nR(TBTA)

Substitute 0.0205mol for n, 8.314J/molK for R, 673K for TB and 293K for TA in above equation.

    ΔEintAB=52(0.0205mol)(8.314J/molK)(673K293K)=162J

Write the expression of first law of thermodynamics.

    ΔEintAB=QWout

Substitute 162J for ΔEintAB and 0 for Q in above equation.

    162J=0WoutWout=162J

Write the expression to calculate the energy in B to C process.

    ΔEintBC=52nR(TCTB)

Substitute 0.0205mol for n, 8.314J/molK for R, 673K for TB and 1023K for TC in above equation,

    ΔEintBC=52(0.0205mol)(8.314J/molK)(1023K673K)=149J

Write the expression of first law of thermodynamics.

    ΔEintBC=QWout

Substitute 149J for ΔEintBC and 0 for Wout in above equation.

    149J=Q0Q=149J

Write the expression to calculate the energy in C to D process.

    ΔEintCD=52nR(TDTC)

Substitute 0.0205mol for n, 8.314J/molK for R, 445K for TD and 1023K for TC in above equation,

    ΔEintCD=52(0.0205mol)(8.314J/molK)(445K1023K)=246J

Write the expression of first law of thermodynamics.

    ΔEintCD=QWout

Substitute 246J for ΔEintCD and 0 for Q in above equation.

    246J=0WoutWout=246J

Write the expression to calculate the energy in D to A process.

    ΔEintDA=52nR(TATD)

Substitute 0.0205mol for n, 8.314J/molK for R, 445K for TD and 293K for TA in above equation,

    ΔEintDA=52(0.0205mol)(8.314J/molK)(293K445K)=65J

Write the expression of first law of thermodynamics.

    ΔEintDA=QWout

Substitute 65J for ΔEintDA and 0 for Wout in above equation.

    65J=Q0Q=65J

Add all the work done found above to find the net work done

    Weng=162J+0+246.3J+0=84.3J

Add the heat energy transferred in the four process given above to find the net heat energy

    Qnet=0+149J+065.0J=84.3J

The change in internal energy during a cyclic process is zero.

Thus, ΔEint=0 for the Otto cycle.

From the above explanation, the complete table is given below.

ProcessQWengΔEint
AB0-162162
BC1490149
CD0246-246
DA-650-65
ABCD84.384.30

Conclusion:

Therefore, the complete table

ProcessQWengΔEint
AB0-162162
BC1490149
CD0246-246
DA-650-65
ABCD84.384.30

(c)

Expert Solution
Check Mark
To determine

The heat input during BC.

Answer to Problem 22.82CP

The heat input during BC is 149J.

Explanation of Solution

From part (b), the heat input during BC, Qh is 149J.

Thus, the heat input during BC is 149J.

Conclusion:

Therefore, the heat input during BC is 149J.

(d)

Expert Solution
Check Mark
To determine

The heat exhaust during DA.

Answer to Problem 22.82CP

The heat exhaust during DA, QC is 65.0J.

Explanation of Solution

From part (b)

The heat exhaust during DA, QC is 65.0J.

Thus, the heat exhaust during DA, QC is 65.0J.

Conclusion:

Therefore, the heat exhaust during DA, QC is 65.0J.

(e)

Expert Solution
Check Mark
To determine

The net work output.

Answer to Problem 22.82CP

The net work output is Weng=84.3J.

Explanation of Solution

From part (b)

The net work output is Weng=84.3J.

Thus, the net work output is Weng=84.3J.

Conclusion:

Therefore, the net work output is Weng=84.3J.

(f)

Expert Solution
Check Mark
To determine

The thermal efficiency.

Answer to Problem 22.82CP

The thermal efficiency is 0.565.

Explanation of Solution

Write the expression to calculate the thermal efficiency.

    e=WengQh

Conclusion:

Substitute 84.3J for WE and 149J for Qh in above equation.

    e=84.3J149J=0.565

Therefore, the thermal efficiency is 0.565.

(g)

Expert Solution
Check Mark
To determine

The number of crankshaft revolution per minute.

Answer to Problem 22.82CP

The number of crankshaft revolution per minute is 1.42×103rev/min.

Explanation of Solution

Write the expression to calculate the output power.

    P=f2Weng

Here, f is the angular speed of the crankshaft.

Substitute 84.3J/cycle for Weng and 1kW for P in above equation.

    1kW×1000J/s1kW=f120(84.3J/cycle)f=1.42×103rev/min

Thus, the number of crankshaft revolution per minute is 1.42×103rev/min.

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Chapter 22 Solutions

Physics for Scientists and Engineers, Technology Update (No access codes included)

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