Find the amount of natural gas required in ft 3 and lbm for generating for electricity for each year.

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Answer 1

Question

Chapter 13, Problem 19P

To determine

Find the amount of natural gas required in ft3 and lbm for generating for electricity for each year.

Expert Solution & Answer

Answer to Problem 19P

The amount of natural gas required in ft3 and lbm for generating for electricity for each year is calculated and tabulated in Table 1.

Explanation of Solution

Given data:

Refer to problem 13-19 accompanying table in the textbook.

The average efficiency of the power plant is 35%.

The heating value of the natural gas is 1000 Btuft3 (22000 Btulbm).

Formula used:

Formula to calculate the power plant efficiency is,

Power plant effeicency=Energy generatedEnergy input from fuel

Rearrange the equation,

Energy input from fuel=Energy generatedpower plant effeicency (1)

Convert Btu to lbm,

1 Btu=122000 lbm [∴ 22000 Btulbm=1]=4.5454×10−5 lbm (2)

Convert lbm to ft3,

1000 Btuft3=22000 Btulbm1000 1ft3=22000 1lbm1ft3=22 1lbm1 lbm=22 ft3 (3)

The value of the 1 Btus is,

1 Btus=1.055 kW (4)

Convert 1 hr into seconds,

1 hr=3600 s

Rearrange the equation,

1 s=13600 hr (5)

Substitute equation (5) in equation (4),

1 Btu13600 hr=1.055 kW1 Btu=1.0553600 kWhr1 Btu=2.93×10−4 kWhr

Rearrange the equation,

1 kWhr=12.93×10−4 Btu=3412.96 Btu

Calculation:

Converting the given data from kWh to Btu:

Substitute 3412.96 Btu for 1 kWhr in 346.2399×109 kWhr for the year 1980,

346.2399×109 kWhr=(346.2399×109)(3412.96 Btu)=1.181702929×1015 Btu=1181702.929×109 Btu

Substitute 3412.96 Btu for 1 kWhr in 372.7652×109 kWhr for the year 1990,

372.7652×109 kWhr=(372.7652×109)(3412.96 Btu)=1.272232717×1015 Btu=1272232.717×109 Btu

Substitute 3412.96 Btu for 1 kWhr in 601.0382×109 kWhr for the year 2000,

601.0382×109 kWhr=(601.0382×109)(3412.96 Btu)=2.051319335×1015 Btu=2051319.335×109 Btu

Substitute 3412.96 Btu for 1 kWhr in 751.8189×109 kWhr for the year 2005,

751.8189×109 kWhr=(751.8189×109 kWhr)(3412.96 Btu)=2.565927833×1015 Btu=2565927.833×109 Btu

Substitute 3412.96 Btu for 1 kWhr in 773.8234×109 kWhr for the year 2010,

773.8234×109 kWhr=(773.8234×109)(3412.96 Btu)=2.641028311×1015 Btu=2641028.311×109 Btu

Substitute 3412.96 Btu for 1 kWhr in 1102.762×109 kWhr for the year 2020,

1102.762×109 kWhr=(1102.762×109)(3412.96 Btu)=3.763682596×1015 Btu=3763682.596×109 Btu

Substitute 3412.96 Btu for 1 kWhr in 992.7706×109 kWhr for the year 2030,

992.7706×109 kWhr=(992.7706×109)(3412.96 Btu)=3.388286347×1015 Btu=3388286.347×109 Btu

Now find the energy input fuel for each year in Btu for natural gas:

Substitute 1181702.929×109 Btu for energy generated and 0.35 for power plant efficiency in equation (1) to find energy input from fuel in 1980,

Energy input from fuel=1181702.929×109 Btu0.35=3.376294083×1015 BtuEnergy input from fuel=3376294.083×109 Btu

Substitute 1272232.717×109 Btu for energy generated and 0.35 for power plant efficiency in equation (1) to find energy input from fuel 1990,

Energy input from fuel=1272232.717×109 Btu0.35=3.63495062×1015 BtuEnergy input from fuel=3634950.62×109 Btu

Substitute 2051319.335×109 Btu for energy generated and 0.35 for power plant efficiency in equation (1) to find energy input from fuel 2000,

Energy input from fuel=2051319.335×109 Btu0.35=5.860912386×1015 BtuEnergy input from fuel=5860912.386×109 Btu

Substitute 2565927.833×109 Btu for energy generated and 0.35 for power plant efficiency in equation (1) to find energy input from fuel 2005,

Energy input from fuel=2565927.833×109 Btu0.35=7.33122238×1015 BtuEnergy input from fuel=7331222.38×109 Btu

Substitute 2641028.311×109 Btu for energy generated and 0.35 for power plant efficiency in equation (1) to find energy input from fuel 2010,

Energy input from fuel=2641028.311×109 Btu0.35=7.545795174×1015 BtuEnergy input from fuel=7545795.174×109 Btu

Substitute 3763682.596×109 Btu for energy generated and 0.35 for power plant efficiency in equation (1) to find energy input from fuel 2020,

Energy input from fuel=3763682.596×109 Btu0.35=1.075337885×1016 BtuEnergy input from fuel=10753378.85×109 Btu

Substitute 3388326.347×109 Btu for energy generated and 0.35 for power plant efficiency in equation (1) to find energy input from fuel 2030,

Energy input from fuel=3388286.347×109 Btu0.35=9680818.134×109 Btu

Now convert Btu to lbm as follows by using the relation 1 Btu=4.5454×10−5 lbm,

Substitute 4.5454×10−5 lbm for 1 Btu in 3376294.083×109 Btu for the year 1980,

3376294.083×109 Btu=(3376294.083×109)(4.5454×10−5 lbm)=1.5346607×1011 lbm≅1.53×1011 lbm

Substitute 4.5454×10−5 lbm for 1 Btu in 3634950.62×109 Btu for the year 1990,

3634950.62×109 Btu=(3634950.62×109)(4.5454×10−5 lbm)=1.652230×1011 lbm≅1.65×1011 lbm

Substitute 4.5454×10−5 lbm for 1 Btu in 5860912.386×109 Btu for the year 2000,

5860912.386×109 Btu=(5860912.386×109)(4.5454×10−5 lbm)=2.664019×1011 lbm≅2.66×1011 lbm

Substitute 4.5454×10−5 lbm for 1 Btu in 7331222.38×109 Btu for the year 2005,

7331222.38×109 Btu=(7331222.38×109)(4.5454×10−5 lbm)=3.3323×1011 lbm≅3.33×1011 lbm

Substitute 4.5454×10−5 lbm for 1 Btu in 7545795.174×109 Btu for the year 2010,

7545795.174×109 Btu=(7545795.174×109)(4.5454×10−5 lbm)=3.429865×1011 lbm≅3.43×1011 lbm

Substitute 4.5454×10−5 lbm for 1 Btu in 10753378.85×109 Btu for the year 2020,

10753378.85×109 Btu=(10753378.85×109)(4.5454×10−5 lbm)=4.88784×1011 lbm≅4.89×1011 lbm

Substitute 4.5454×10−5 lbm for 1 Btu in 9680818.134×109 Btu for the year 2030,

9680818.134×109 Btu=(9680818.134×109) (4.5454×10−5 lbm)=4.4003190×1011 lbm≅4.40×1011 lbm

Now convert Form lbm to ft3 by using the relation 1lbm=22 ft3 as follows,

Substitute 22 ft3 for 1 lbm in 1.5346607×1011 lbm for the year 1980,

1.5346607×1011 lbm=(1.5346607×1011)(22 ft3)=3.37625×1012 ft3≅3.38×1012 ft3

Substitute 22 ft3 for 1 lbm in 1.652230×1012 lbm for the year 1990,

1.652230×1011 lbm=(1.652230×1011)(22 ft3)=3.6354906 ×1012 ft3≅3.63 ×1012 ft3

Substitute 22 ft3 for 1 lbm in 2.664019×1012 lbm for the year 2000,

2.664019×1011 lbm=(2.664019×1011)(22 ft3)=5.8608418×1012 ft3≅5.86×1012 ft3

Substitute 22 ft3 for 1 lbm in 3.33233×1010 lbm for the year 2005,

3.33233×1011 lbm=(3.33233×1011)(22 ft3)=7.331126×1012 ft3≅7.33×1012 ft3

Substitute 22 ft3 for 1 lbm in 3.429865×1011 lbm for the year 2010,

3.429865×1011 lbm=(3.429865×1011)(22 ft3)=7.545703×1012 ft3≅7.55×1012 ft3

Substitute 22 ft3 for 1 lbm in 4.88784×1011 lbm for the year 2020,

4.88784×1011 lbm=(4.88784×1011)(22 ft3)=1.0753358×1013 ft3≅1.08×1013 ft3

Substitute 22 ft3 for 1 lbm in 4.400319×1011 lbm for the year 2030,

4.400319×1011 lbm=(4.400319×1011)(22 ft3)=9.6807018×1012 ft3≅9.68×1012 ft3

Therefore, the amount of natural gas in ft3 and lbm for generating electricity for each year required is tabulated as in Table 1 with approximately rounded values for amount of natural gas needed in lbm and amount of natural gas needed in ft3.

Engineering Fundamentals: An Introduction to Engineering, Chapter 13, Problem 19P

Conclusion:

Hence, the amount of natural gas in ft3 and lbm for generating electricity for each year has been calculated.

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