Microsoft Word - Cengel and Boles TOC _2-03-05_.doc

(ff) #1
(13–19)

(13–20)

(13–21)

Similarly, the specific heats of a gas mixture can be expressed as

(13–22)

(13–23)

Notice that properties per unit mass involve mass fractions(mfi) and prop-
erties per unit mole involve mole fractions(yi).
The relations given above are exact for ideal-gas mixtures, and approxi-
mate for real-gas mixtures. (In fact, they are also applicable to nonreacting
liquid and solid solutions especially when they form an “ideal solution.”)
The only major difficulty associated with these relations is the determina-
tion of properties for each individual gas in the mixture. The analysis can be
simplified greatly, however, by treating the individual gases as ideal gases,
if doing so does not introduce a significant error.

Ideal-Gas Mixtures
The gases that comprise a mixture are often at a high temperature and low
pressure relative to the critical-point values of individual gases. In such cases,
the gas mixture and its components can be treated as ideal gases with negligi-
ble error. Under the ideal-gas approximation, the properties of a gas are not
influenced by the presence of other gases, and each gas component in the
mixture behaves as if it exists alone at the mixture temperature Tmand mix-
ture volume Vm. This principle is known as the Gibbs–Dalton law,which is
an extension of Dalton’s law of additive pressures. Also, the h,u,cv, and cpof
an ideal gas depend on temperature only and are independent of the pressure
or the volume of the ideal-gas mixture. The partial pressure of a component in
an ideal-gas mixture is simply PiyiPm, where Pmis the mixture pressure.
Evaluation of uor hof the components of an ideal-gas mixture during
a process is relatively easy since it requires only a knowledge of the initial
and final temperatures. Care should be exercised, however, in evaluating the
sof the components since the entropy of an ideal gas depends on the pres-
sure or volume of the component as well as on its temperature. The entropy
change of individual gases in an ideal-gas mixture during a process can be
determined from

(13–24)

or

¢sis°i,2 s°i,1Ru ln (13–25)

Pi,2
Pi,1

cp,i ln

Ti,2
Ti,1

Ru ln

Pi,2
Pi,1

¢sis°i,2 s°i,1Ri ln

Pi,2
Pi,1

cp,i ln

Ti,2
Ti,1

Ri ln

Pi,2
Pi,1

cp,ma

k

i 1

mfi cp,i¬ 1 kJ>kg#K 2 and¬cp,ma


k

i 1

yi cp,i¬ 1 kJ>kmol#K 2


cv,ma

k

i 1

mfi cv,i¬ 1 kJ>kg#K 2 and¬cv,ma


k

i 1

yi cv,i¬ 1 kJ>kmol#K 2


sma

k

i 1

mfi si¬ 1 kJ>kg#K 2 and¬sma


k

i 1

yi si¬ 1 kJ>kmol#K 2


hma

k

i 1

mfi hi¬ 1 kJ>kg 2 and¬hma


k

i 1

yi hi¬ 1 kJ>kmol 2


uma

k

i 1

mfi ui 1 kJ>kg 2 ¬ and¬uma


k

i 1

yiui 1 kJ>kmol 2

690 | Thermodynamics

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