EBK THERMODYNAMICS: AN ENGINEERING APPR
EBK THERMODYNAMICS: AN ENGINEERING APPR
8th Edition
ISBN: 9780100257054
Author: CENGEL
Publisher: YUZU
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Chapter 6.11, Problem 26P

A coal-burning steam power plant produces a net power of 300 MW with an overall thermal efficiency of 32 percent. The actual gravimetric air–fuel ratio in the furnace is calculated to be 12 kg air/kg fuel. The heating value of the coal is 28,000 kJ/kg. Determine (a) the amount of coal consumed during a 24-hour period and (b) the rate of air flowing through the furnace.

(a)

Expert Solution
Check Mark
To determine

The amount of coal consume during a 24 hour period.

Answer to Problem 26P

The amount of coal consume during a 24 hour period is 2.89×106kg_.

Explanation of Solution

Write the expression for thermal efficiency of power plant.

ηth=Wnet,outQin (I)

Here, the net work output of the power plant is Wnet,out and the amount of the heat supplied to the power plant is Qin.

Simplify the Equation (II) as per British thermal unit per hour.

ηth=W˙net,outQ˙inQ˙in=W˙net,outηth (II)

Here, the rate of heat transfer of the power plant is Q˙in and the rate of required output of the power plant is W˙net,out.

Determine the amount heat input to the power plant with respect to time.

Qin=Q˙inΔt (III)

Here, the change in with respect with time is Δt.

Determine the heat supplied to the power plant.

Qin=mcoal×qHVmcoal=QinqHV (IV)

Here, the mass of the coal is mcoal and the value of heating coal is qHV.

Determine the rate of mass of coal consumed during this period.\

m˙coal=mcoalΔt (V)

Conclusion:

Substitute 300MW for W˙net,out and 0.32 for ηth in Equation (II).

Q˙in=(300MW)(0.32)=(300MW)(0.32)=937.5MW

Substitute 937.5MJ/s for Q˙in and 24hours for Δt in Equation (III).

Qin=(937.5MJ/s)(24h)=(937.5MJ/s)(24h×3600sec1h)=81000000MJ=8.1×107MJ

Substitute 8.1×107MJ for Qin and 28000kJ/kg for qHV in Equation (IV).

mcoal=(8.1×107MJ)(28000kJ/kg)=(8.1×107MJ)(28000kJ/kg×(103MJ/kg1kJ/kg))=2892857kg2.89×106kg

Thus, the amount of coal consume during a 24 hour period is 2.89×106kg_.

Substitute 2.89×106kg for mcoal and 24hours for Δt in Equation (V).

m˙coal=(2.89×106kg)(24h)=(2.89×106kg)(24h×(3600sec1h))=33.48kg/s

(b)

Expert Solution
Check Mark
To determine

The rate of air flowing through the furnace.

Answer to Problem 26P

The rate of air flowing through the furnace is 401.8kg/s_.

Explanation of Solution

Determine the rate of air mass flowing through the furnace.

m˙air=(AF)×m˙coal (VI)

Here, the ration of air-fuel is AF.

Conclusion:

Substitute 12kgair/kgfuel for AF and 33.48kg/s for m˙coal in Equation (VI).

m˙air=(12kgair/kgfuel)×(33.48kg/s)=401.8kg/s

Thus, the rate of air flowing through the furnace is 401.8kg/s_.

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Chapter 6 Solutions

EBK THERMODYNAMICS: AN ENGINEERING APPR

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