THERMODYNAMICS: ENG APPROACH LOOSELEAF
THERMODYNAMICS: ENG APPROACH LOOSELEAF
9th Edition
ISBN: 9781266084584
Author: CENGEL
Publisher: MCG
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Chapter 6.11, Problem 143RP
To determine

The amount of oil a family of four will save per year by replacing the standard shower heads by the low-flow ones.

The amount of money a family of four will save per year by replacing the standard shower heads by the low-flow ones.

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Answer to Problem 143RP

The amount of oil a family of four will save per year by replacing the standard shower heads by the low-flow ones is 29.1gal/year_.

The amount of money a family of four will save per year by replacing the standard shower heads by the low-flow ones is $81.5/year_.

Explanation of Solution

Determine the rate of water saved volume of the low-flow shower head a family of four will save per year.

ν˙saved=[(ν1ν2)×(t/(personday))×(n)×(number of days per year)] (I)

Here, the initial volume of the low-flow shower head is ν1, the final volume of the low-flow shower head is ν2, the time is t, and the number person in family is n.

Determine the mass flow rate of water of the low-flow shower head.

m˙saved=ρwater×ν˙saved (II)

Here, the density of water is ρwater.

Determine the amount of energy saved in the low-flow shower head.

Esaved=(m˙watercpΔT)=m˙watercp(T1T2) (III)

Here, the specific heat of water is cp, the initial temperature of the low-flow shower head is T1, and the final temperature of the low-flow shower head is T2.

Determine the amount fuel saved in the low-flow shower head.

Fuelsaved=Esaved(ηfuel)(heatingvalueof fuel) (IV)

Here, the efficiency of the fuel in the low-flow shower head is ηfuel.

Determine the amount of money saved in the low-flow shower head.

Moneysaved=(fuel saved)×(unit cost of fuel) (V)

Conclusion:

Substitute 13.3L/min for ν1, 10.5L/min for ν2, 6 min for t, 4 for n, 356 for number of days per year in Equation (I).

ν˙saved=[(13.310.5)L/min×(6min/(personday))×(4persons)×(365days/year)]=[2.8L/min×(6min/(personday))×(4persons)×(365days/year)]=24,528L/year

Substitute 1kg/L for ρ and 24,528L/year for ν˙saved in Equation (II).

m˙saved=(1kg/L)×(24,528L/year)=24,528kg/year

Substitute 24,528kg/year for m˙saved, 4.18kJ/kg°C for cp, 42°C for T1, and 15°C for T2 in the Equation (III).

Esaved=(24,528kg/year)×(4.18kJ/kg°C)×(42°C15°C)=(24,528kg/year)×(4.18kJ/kg°C)×(27°C)=2768230kJ/year

Substitute 2768230kJ/year for Esaved, 0.65 for ηfuel, 146,300kJ/gal for heating value of fuel in Equation (IV).

Fuelsaved=(2768230kJ/year)(0.65)×(146,300kJ/gal)=(2768230kJ/year)(0.65)×(146,300kJ/gal)=(2768230kJ/year)(95095kJ/gal)=29.1gal/year

Thus, the amount of oil a family of four will save per year by replacing the standard shower heads by the low-flow ones is 29.1gal/year_.

Substitute 29.1gal/year for fuel saved and $2.80/gal for unit cost of fuel in Equation (V).

Moneysaved=(29.1gal/year)×($2.80/gal)=$81.5/year

Thus, the amount of money a family of four will save per year by replacing the standard shower heads by the low-flow ones is $81.5/year_.

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Chapter 6 Solutions

THERMODYNAMICS: ENG APPROACH LOOSELEAF

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